Cobalamin assay

ABSTRACT

The present invention provides a specific binding partner for holoTC having a specificity for holoTC over apoTC of at least 40-fold and an assay method for assaying for holoTC in a sample, the method comprising contacting the sample with a specific binding partner for holoTC and detecting the resultant conjugates.

The present invention relates to a method of assaying for holotranscobalamin (holoTC) in samples of biological, especially mammalian origin, and to specific binding partners (sbp's) for transcobalamin (TC) for use in such assays, as well as to their production.

HoloTC is the complex between cobalamin and its serum transport protein transcobalamin.

Cobalamin or vitamin B₁₂ is a water soluble vitamin which forms part of the vitamin B complex found in foods. The core molecule consists of a corrin ring of four pyrole units which surround a cobalt atom. Cobalamin is the only vitamin which cannot be synthesised by animals and must be absorbed from food in the gut. It is synthesised by micro-organisms, in particular by anaerobic bacteria and yeasts.

Cobalamin functions in vivo as a co-enzyme and cobalamin enzymes are known to catalyse three types of reaction: (i) intra-molecular rearrangements, for example, the formation of succinyl CoA from L-methylmalonyl CoA; (ii) methylations, for example, the formation of methionine by methylation of homocysteine; and (iii) reduction of ribonucleotides to deoxyribonucleotides in some micro-organisms. It is also thought that cobalamin deficiency may disturb cytokine and growth factor regulation (see Miller, Nutrition Reviews 60: 142-144 (2002) and Scalabrino et al. J. Neuroimmunology 127:37-42(2002)).

In the process of digestion, cobalamin released in food by cooking or by the acid environment of the stomach is bound by a salivary protein called haptocorrin, hereinafter referred to as HC (but which is also referred to in the art as R-binder or transcobalamins I and III collectively), to form a complex. Pancreatic enzymes digest the cobalamin-haptocorrin complex, holohaptocorrin (holoHC), in the ileum, liberating cobalamin which is then bound to a protein called intrinsic factor, which is secreted by the gastric mucosa, to form a further complex. The cobalamin-intrinsic factor complex binds to a specific receptor in the lining of the terminal ileum, whereupon it is dissociated by a releasing factor and the cobalamin is transported actively across the membrane of the ileum and is secreted into the blood stream bound to its transporter protein transcobalamin (TC).

It should be recognised that TC has in the past been referred to as transcobalamin II (TCII). TC, apoTC and holoTC are used herein to denote TCII, apo-TCII and holo-TCII respectively.

Cobalamin does not circulate in the blood in a free form in any appreciable amount. About 99% of the cobalamin is bound by one of HC, TC and albumin.

The protein responsible for transporting cobalamin to target tissues is TC. TC is a critical trace protein without which cobalamin cannot cross cell membranes. Despite this important metabolic function only about 6-25% of cobalamin in the serum is bound to TC and most is carried by HC. TC is a single chain polypeptide of 45 kDa found primarily in serum, seminal fluid and cerebro-spinal fluid. Cobalamin bound TC (holo-TC), attaches to specific receptors on cell membranes and, once bound, the holo-TC complex is taken into cells by pinocytosis.

TC is synthesised by the liver, vascular endothelium, enterocytes, macrophages and fibroblasts and circulates predominantly as apo-TC, i.e. lacking bound cobalamin. It has a short half life of approximately 90 minutes.

The amino acid sequence of human TC is believed to be as follows:

(Seq. ID No. 1) MRHLGAFLFL LGVLGALTEM CEIPEMDSHL VEKLGQHLLP WMDRLSLEHL NPSIYVGLRL SSLQAGTKED LYLHSLKLGY QQCLLGSAFS EDDGDCQGKP SMGQLALYLL ALRANCEFVR GHKGDRLVSQ LKWFLEDEKR AIGHDHKGHP HTSYYQYGLG ILALCLHQKR VHDSVVDKLL YAVEPFHQGH HSVDTAAMAG LAFTCLKRSN FNPGRRQRIT MAIRTVREEI LKAQTPEGHF GNVYSTPLAL QFLMTSPMPG AELGTACLKA RVALLASLQD GAFQNALMIS QLLPVLNHKT YIDLIFPDCL APRVMLEPAA ETIPQTQEII SVTLQVLSLL PPYRQSISVL AGSTVEDVLK KAHELGGFTY ETQASSSGPY LTSVMGKAAG EREFWQLLRD PNTPLLQGIA DYRPKDGETI ELRLVSW The first 18 amino acids, shown in italics, are a leader sequence not found in the mature protein circulating in the blood. In addition, there are a number of known polymorphisms, of which the substitution of arginine in place of proline at position 259 (shown in bold) (Seq. ID No. 2) is the most common and is equally as abundant as the sequence shown. Other described polymorphisms are M198T, I219L, Q234R and S376L.

Since cobalamin must be absorbed from food, any conditions which result in impaired gastric function, for example, gastroenteritis or conditions resulting in gastric atrophy, or an inability to produce functional haptocorrin, intrinsic factor, releasing factor, TC or TC receptors, can result in impaired uptake of cobalamin and resultant deficiency.

Certain population sub-groups, for example the aged, pregnant women, patients with chronic or acute gastrointestinal disease, those suffering from certain autoimmune diseases, those with a family history of pernicious anaemia and AIDS sufferers, are particularly prone to cobalamin deficiency.

The clinical manifestations of cobalamin deficiency are varied and numerous but primarily involve anaemia, megaloblastic haematopoiesis and functional and structural disorders of the nervous system. Around 60% of individuals diagnosed as being deficient in cobalamin are anaemic, but in many neurological symptoms are the only clinical signs observed. Around 10% of patients exhibit psychiatric symptoms and around 40% exhibit both neurological and psychiatric symptoms.

Early diagnosis of cobalamin deficiency is crucial to ensure a good prognosis for patients, since some of the manifestations of cobalamin deficiency, particularly the neuropsychiatric effects, are irreversible if not detected and alleviated by cobalamin therapy quickly.

It is desirable therefore to accurately assess the cobalamin level of an individual in an expedient and efficient manner, with a view to establishing whether or not the individual may be suffering from cobalamin deficiency. Since it is TC that is responsible for transporting cobalamin into cells, the holoTC content of a body sample provides a better indicator of cobalamin deficiency than does the total cobalamin content.

Because holoTC is present in body fluids in such low concentrations, previous assay methods have generally not been entirely satisfactory. A patient with a serum holoTCII level at the lower end of the normal range typically has a serum holoTCII concentration of around 30×10⁻¹² M and conventional assays based upon physical absorption of TC onto a solid substrate, e.g. silica, have a lower limit of detection at around 40×10⁻¹² M. Such assays are therefore of relatively little value for assessment of holo-TCII deficiency (see Wickramasinghe et al., J Clin Path 49: 755-758 (1996)).

In WO00/17659, it was proposed that specific binding partners (sbp's) for TCII or holo-TCII be used in an assay method for holo-TCII, thereby providing a holo-TCII assay method which could more readily be adapted to automation and the requirements of a high-throughput analytical laboratory.

The inventors have now discovered a particular epitope of holoTC for which sbp's can be generated which have excellent discrimination between apoTC and holoTC. Further, by creating a cyclic peptide “mimotope” mimic of that holoTC epitope, sbp's can be produced which allow an assay method for holoTCII which is highly susceptible to automation and use in high throughput assays.

For assay methods easily adaptable to the major automatic platforms, e.g. Centaur® (Bayer, Germany), Elecsys® (Roche) or Axsym® (Abbott), sbp's for holoTC are needed. However, no sbp's with the discrimination between apoTC and holoTC required for such assay formats have yet been described. Assay methods utilising TC-specific binding partners are suitable for automation but require extra steps to separate and measure the holoTC content making the methods more difficult to automate and reducing the number of commercial platforms which can successfully handle the assay.

There are only a few literature reports of polyclonal antibodies with affinities for human TC (see Morelli et al J Lab Clin Med 89: 645-652 (1976); vanKapel et al Biochem Biophys Acta 676: 307-13 (1981); Quadros et al J Biol Chem 261: 15455-60 (1986); and Nexø et al Clin Chem, 46:1643-9 (2000)) and even fewer literature reports of monoclonal antibodies with affinities for human TC (see Carmel et al., Proc Soc Exp Biol Med 188: 77-81 (1988) and McLean et al Blood 89:235-242 (1997)). None of these authors claims to have found binders which discriminate between apoTC and holoTC. Quadros (Biochem Biophys Res Comm 222: 149-154 (1996)), used antibodies which blocked the binding of cobalamin to apoTC to study the transport of cobalamin into cells.

In fact, it has not been entirely clear whether the differences in physicochemical properties between the apo-form and the holo-form of transcobalamin are sufficient to allow development of antibodies, or other sbp's, specific for only one of the forms. Indeed reports that the natural holoTC receptor also binds apoTC with high affinity (see Nexø et al., Biochem Biophys Acta 628:190-200 (1980)) and the fact that no holoTC specific antibodies have been reported suggested that in practice it may not be possible to produce such sbp's.

Sbp's (i.e. specific binding ligands) such as antibodies, have two particular properties which are of great significance to their suitability for use in assays such as those of the present invention. These are their affinity and their specificity. Affinities for antibodies range from about 10⁷ to about 10¹¹ M⁻¹ and other sbp's can show affinities in a similar range. High affinity antibodies (>10⁹ M⁻¹) are generally preferred in the art for diagnostic assays because they allow the capture of analytes at low concentrations.

Whether a sbp of high affinity can be found for a particular analyte is intrinsically dependent upon the surface charge and topology of the analyte. If suitable motifs (epitopes) exist then antibody, peptide, DNA/RNA oligomer or organic chemical binders which correspond to this motif can be generated by standard methods. Thus, for example, once an high affinity antibody to a particular epitope has been identified, this indicates that sbp's of other types with affinity for this epitope can be found. The affinity depends upon the intrinsic nature of the epitope and upon the degree of correspondence between the epitope and the binding site of the sbp (sometimes referred to as the paratope).

The second significant property shown by sbp's is specificity. This is the ability of an sbp to recognise its binding partner to the exclusion of other molecules found in the sample being tested. This typically depends upon which epitope of a molecule is recognised by the sbp, how unique this epitope is to the analyte molecule, and how exactly the binding site of the sbp corresponds. Since a binding region having high correspondence to the charge and topology of the analyte is required both for high affinity and high specificity sbp's, sbp's with high specificity generally also have high affinity.

The method by which sbp's are identified typically relies on repeated rounds of screening under increasingly stringent conditions in order to identify sbp's with a very high affinity for their binding partner. This identifies extremely strongly binding sbp's and it is assumed that the strongest binding ligand will be the most specific and show the greatest discrimination.

In contrast to the usual technique, we selected for antibodies of poor affinity and examined these. Unexpectedly, by this method, antibodies have been identified which display good specificity for holoTC over apoTC. These antibodies can be used in holoTC assays and for the identification of “mimotope” mimics of the specific holoTC epitope, from which further holoTC specific ligands can be generated, including those with high affinity as well as high specificity. The antibodies and those generated from the mimotope may in turn be used to identify (experimentally or computationally) the epitope on holoTC which confers the specificity.

The primary antibody identified will be referred to herein as “3C4” and displays at least a 70-fold specificity for holoTC over apoTC. The “3C4” antibody is of relatively weak affinity (Ka<10⁷ M⁻¹).

In a first aspect, the present invention therefore provides a specific binding partner for holoTC having a specificity for holoTC over apoTC of at least 40-fold, preferably at least 50-fold, and most preferably at least 70-fold (for example 100-fold or greater).

The sbp preferably shows the above apo/holo discrimination in the case of both native apo/holoTC and recombinant apo/holoTC. Most preferably the specificity between human native apoTC and holoTC is at least as great as between recombinant apoTC and holoTC.

We have found that at least 7 epitopes exist on human TC and of these at least one (referred to herein as epitope 4) occurs in holoTC and not in apoTC. Further, epitope 4 has been found to be present only in the non-reduced (ie non-denatured) protein and not in the reduced (denatured) protein, which indicates that epitope 4 is a conformational or discontinuous epitope.

Conformational epitopes are antigenic regions consisting of residues which are widely spaced in the primary (linear) sequence of the protein but are brought together in close proximity when the protein folds. Such epitopes cannot be deduced, predicted or modelled from a knowledge of the amino-acid sequence of the protein because they have no correlation to this. Such an epitope exists only in the 3-dimensional conformation of the protein.

The composition and sequence of the amino acids comprising a conformation specific epitope can currently only be deduced from knowledge of the crystal structure of the protein. However, no crystal structure of human holoTC, or TC, or of any of the cobalamin transporting proteins from any species, has been determined. Only a preliminary report on the crystallization of human TC has been published, indicating human TC crystallizes as two independent molecules in an asymmetric unit poorly suited for X-ray diffraction analysis (see Garau et al, Acta Cryst. D57:1890-2 (2001)). It is thus not currently possible to determine the exact epitope of a conformation specific antibody to TC. These preliminary data further indicate that a true, high definition, crystal structure of human TC may be impossible to generate with current methods.

However, the present inventors have surprisingly identified certain amino acids and amino acid regions of the TC sequence which may provide the epitopic region of epitope 4 as described herein.

In a further aspect, therefore, the present invention provides a specific binding partner for holoTC which binds to at least one point in at least one of the regions I, II or III of human TC;

-   I) Leu 39 to Lys 77 and Thr 265 to Lys 269 -   II) Ile 161 to Val 243 -   III) Arg 271 to Asp 297 (or preferably Lys 296).

Preferably, the specific binding partner for holoTC will bind to each of regions I and II, each of regions II and III or each of regions I and III. Most preferably, the specific binding partner will bind to each of regions I II and III.

In the most common human TC sequence, regions I to III will have sequences:

(Seq. ID Nos 3 and 4 respectively) I LPWMDRLSLE HLNPSIYVGL RLSSLQAGTK EDLYLHSLK and TACLK (Seq. ID No. 5) II ILALCLHQKR VHDSVVDKLL YAVEPFHQGH HSVDTAAMAG LAFTCLKRSN FNPGRRQRIT MAIRTVREEI LKAQTPEGHF GNV (Seq ID No. 6) III RVALLASLQD GAFQNALMIS QLLPVLN The amino acid residues thought to be significant are highlighted in bold. More preferably, the regions I to III will have sequences: In the most common human TC sequence, these regions will have sequences:

(Seq ID No. 7) I LPWMDRLSLE HLNPSIYVGL RLSSLQAGTK EDLYLHSLK and TACLK II ILALCLHQKR VHDSVVDKLL YAVEPFHQGH HSVDTAAMAG LAFTCLKRSN FNPGRRQRIT MAIRTVREEI LKAQTPEGHF GNV III RVALLASLQD GAFQNALMIS QLLPVL The amino acid residues thought to be highly significant are highlighted in bold.

Where a binding partner or ligand is described herein as binding to a region of a protein such as TC, this indicates that there is at least one interaction between the binding partner and at least one amino acid in the region. It will be unusual for all amino acids in a region to contribute to ligand binding but, preferably, binding will indicate that the ligand and at least two amino acids in the region interract, more preferably, three, four, five or more amino acids in the region (e.g 8 or 10) will interract with the ligand. Interactions may be measured, for example, by examining the structure of the ligand when crystallised or modelled with the protein. Distances of less than around 0.5 nm are typically considered to indicate interactions.

Preferred specific binding ligands for TC interact with the regions I to III by means of at least one of the significant residues highlighted above. More preferably, specific binding ligands for TC interact with the regions I to III by means of at least one of the highly significant residues indicated above. It is most preferred that at least half of the interactions are with the significant or highly significant residues indicated above.

In the absence of a crystal structure of human TC, mimotope mimics to epitope 4 of TC have been generated by use of the 3C4 antibody. A phage display library of disulfide constrained peptides was screened with the holoTC specific monoclonal antibody (mAb) 3C4 and a series of specific peptides were identified forming two similar motifs (see Example 4). The peptides were specific for mAb 3C4. They did not bind mAb directed to other epitopes on holoTC and binding to mAb 3C4 was blocked by holoTC, thus indicating that they were true mimics of, and competitors with, the holoTC specific epitope 4 (see Example 5).

The peptides, such as mimotopes, described herein are specified in terms of the standard biochemical single-letter codes for naturally occurring amino acids, which are all well known in the art. Of these, particularly significant to the present invention are; alanine (A), cysteine (C), aspartic acid (D), glutamic acid (E), phenylalanine (F), glycine (G), histidine (H), isoleucine (I), lysine (K), leucine (L), methionine (M), asparagine (N), proline (P), glutamine (Q), arginine (R), serine (S), threonine (T), valine (V), tryptophan (W) and tyrosine (Y).

The mimotope provided consists of a constrained peptide with the motif SX₁X₂YX₃WDX₄X₅X₆ where,

-   -   X₁=F, G, L     -   X₂=F, L, R     -   X₃=L, P, Q     -   X₄=M, Q, Y     -   X₅=D, F     -   X₆=M, R (Seq ID No. 8)         or the motif

SFFYSLCYCW (Seq ID No. 9) optionally attached to the surface of a cell or phage.

Such mimotopes and particularly polyhapten constructs thereof are useful in competition assays for holoTC, in which they may carry a suitable label. The mimotopes may also be used to identify alternative specific binding partners for holoTC having specificity for holoTC over apoTC and optionally having high affinity for holoTC.

The present invention therefore provides an assay method for holoTC comprising the use of a (preferably labelled) constrained peptide mimotope comprising the motif SX₁X₂YX₃WDX₄X₅X₆ where,

-   -   X₁=F, G, L     -   X₂=F, L, R     -   X₃=L, P, Q     -   X₄=M, Q, Y     -   X₅=D, F     -   X₆=M, R         or the motif         SFFYSLCYCW         optionally attached to a cell or phage, or a construct of two or         more (e.g. 2, 3, 4, 5 or 6) such mimotopes. Such an assay method         may be a method in which holoTC is pre-bound to a specific         binding partner for holoTC and the remaining binding sites are         detected by means of the mimotope. Preferably, however, the         assay method is a competition assay in which the above described         mimotope or construct thereof functions as a competitor of         holoTC for specific binding sites on a specific binding ligand         for holoTC.

In such an assay method, the sbp will generally be immobilised or immobilisable.

Typically, such an assay will involve contacting a sample from a human or animal subject with a limited quantity of a specific binding partner for holoTC having a restricted number of binding sites. HoloTC from the sample and the mimotope or mimotope construct then compete for binding to these sites. The bound and unbound portions are then preferably separated (e.g. by precipitation due to crosslinking or addition of a precipitation agent, rinsing of a substrate immobilized sbp, filtration, magnetic separation, centrifugation, change of conditions such as pH etc) to give a bound fraction and an unbound fraction. The holoTC in the sample may then be determined by measuring the amount of (optionally labelled) mimotope or mimotope polyhapten construct bound in the bound fraction or remaining unbound in the unbound fraction and relating this to the quantity of holoTC present in the sample. Greater amounts of mimotope binding to the sbp represent lesser amounts of holoTC in the sample. Where the bound or unbound mimotope or mimotope construct is capable of detection without separation of the bound and unbound fractions, e.g. by changes in light transmission following addition of an agglutination promoting agent or of fluorescence polarization where the holoTC sbp, the mimotope or construct is fluorophore-labelled, etc., the assay method need not involve separation of the bound and unbound fractions.

Suitable samples for the assessment of holoTC concentrations in all relevant aspects of the present invention may be any holoTC containing sample, e.g. a body fluid or tissue sample, or a sample prepared therefrom. Preferably, however the sample will be a body fluid, for example seminal fluid, cerebro-spinal fluid or amniotic fluid, more preferably a blood derived sample, particularly a serum sample.

Suitable specific binding partners in all aspects of the invention including assays for holoTC include antibodies, single chain antibodies, antibody fragments, antibody constructs, oligopeptides (e.g. constrained cyclic peptides), oligonucleotides (e.g. DNA or RNA aptamers), small organic molecules, etc., any of which may be immobilised or immobilisable. Preferred specific binding partners (e.g. for such assays) are antibodies, particularly monoclonal antibodies and their fragments and constructs (e.g. F_(AB) fragments) and particularly preferred is monoclonal antibody 3C4 as described herein, its fragments and its constructs. Preferred sbps also include oligonucleotide aptamers (ie short, preferably constrained, sequences of double- or more usually single-stranded DNA or RNA). In certain cases these aptamers may be of value with a lower degree of specificity than is generally preferable. For example, they may show an at least 8-fold, preferably at least 10-fold and more preferably at least 15-fold specificity for holoTC over apoTC. Obviously it remains preferable that such aptamers have the higher specificity described above.

Particularly preferred sbps are single chain antibody fragments (scFv) comprising the heavy and light chain variable regions of the complete antibodies joined by a linker into a single polypeptide, coded for by a single DNA sequence. These may be prepared from the mRNA coding for the full antibodies by techniques known in the art. Such scFvs have the advantage that they are significantly smaller than complete antibodies and thus may be arrayed more closely and formed into constructs with a greater density of binding sites. They are also expressible in E. Coli and/or in bacteriophage and thus may be made in large quantities more easily than by expression in mammalian cell lines and are more amenable to genetic modification and optimisation. ScFvs are readily sequenced and the sequences of the scFvs corresponding to TC2 and 3C4 are given in Example 11 (Table 6). These scFvs were compared with the corresponding whole antibodies and found to have similar specificities (Example 11).

In addition to identifying scFvs with equivalent binding regions to TC2 and 3C4, the scFvs corresponding to 3C4 have been subjected to 2 rounds of affinity maturation by mutation and screening (see Example 13). Thus, where herein the use of antibody TC2 is indicated, it is similarly preferred that single chain antibody fragment ScFv_TC2, or an affinity matured equivalent, be used and where herein the use of antibody 3C4 is indicated, it is similarly preferred that single chain antibody fragment ScFv_(—)3C4, or an affinity matured equivalent, be used.

The single chain antibody fragments may be labelled for detection by any of the methods described herein and where they are so labelled, it is preferred that the label be attached to the scFv via the linking region. Most preferably, the label will be attached to the linking region via a functional side chain, particularly the SH group of cysteine or the OH group of tyrosine.

The present invention thus further provides single chain antibodies corresponding to each of the antibodies described in the Examples herein and particularly to scFvs specific for epitopes 4 and 5 as described herein. Most preferable are TC2_ScFv and 3C4_ScFv as shown in Table 6 and the affinity matured equivalents indicated in Tables 9 and 10.

In order to improve the binding characteristics of 3c4_scFv, it was subjected to genetic modification and optimization (affinity maturation). Random mutagenesis libraries of size 10⁵-10⁶ individual clones were generated and expressed on the surface of bacteriophage using techniques known in the art. The affinity maturation of scFv 3C4 resulted in 12 novel scFv clones with higher affinity and retained specificity for holoTC (Table 9). The best scFv clones were subjected to a second round of mutagenesis and library construction from which 9 novel scFv were selected, of which six with higher affinity than the best of the 1st generation library (clone 3.10E5 in Table 10). A method for performing affinity maturation by use of well known techniques is described in Example 15.

Single-chain antibody fragments of monoclonal antibodies may be constructed, using standard procedures (e.g. McCafferty J, Hoogenboom H R, and Chiswell D J (ed.) (1996) Antibody Engineering—A practical approach, IRL Press, Oxford, UK). For convenience, commercially available kits may be used, such as the QuickPrep® mRNA Purification Kit, for mRNA preparation, the Mouse ScFv Module for scFv antibody preparation, and the Expression Module for expression of the scFv antibody as soluble protein in E. Coli (Amersham Biosciences). A typical method for the production of scFvs from any of the complete IgG antibodies described herein, by use of well known techniques and commercially available kits is described in Example 12.

Specific binding partners suitable for an assay comprising use of the mimotopes described above will preferably be specific for an epitope overlapping with epitope 4 as described herein. Typically, such ligands will be specific for epitope 4.

Methods for the immobilisation of any of the ligands described herein are well known in the art and include covalent bonding such as by amide, disulphide or amine bond formation (e.g. by use of a carbodiimide coupling agent), physicochemical absorption such as absorption of thiols onto gold, coupling of immobilised specific binding partners (such as biotin and streptavidin or goat anti-mouse antibodies to capture murine mAbs) and the creation of insoluble antibody precipitates. Immobilised ligands may be pre-bound to a substrate or may be immobilised during an assay by the addition of a substrate or precipitation agent carrying a suitable binding partner.

Suitable substrates for immobilization of any of the specific binding ligands described herein are well known and include surfaces such as glass or polymeric surfaces, especially the surfaces of dishes or microtitre assay plates or sheets particularly the inside of the wells thereof, the surfaces of SPR slides, AFM slides etc., the surfaces of beads such as glass or polymeric beads, membranes, such as cellulose or polymeric membranes and also gels and macromolecules such as resins and dendrimers which swell or solubilise under certain conditions but may be precipitated or separated by techniques such as filtration or size exclusion chromatography. Most preferred as substrates are magnetisable polymeric beads such as those available from Bangs-Laboratories (e.g. Estapor® EMI-100/40), SPR chips (e.g. from Biacore) and the surfaces of microtitre plates.

Labelled species as described herein may be labelled for detection by any of a large number of methods known in the art. Such labelling methods include fluorescent labelling (e.g. with fluorosceine, rhodamine, green fluorescent protein etc.), luminescent labelling with proteins such a luciferase or with chemiluminescent agents (such as luminol (3-aminophthalphdrazide) or near-infrared luminescent metal azatriphenylene complexes), chromatic labelling with light absorbing or scattering agents such as dyes, enzymatic labelling (e.g. with alkaline peroxidase), radiolabelling with nuclei such as tritium, carbon-14, or radioiodine, with or without the use of scintillation agents, and magneto labelling, especially with paramagnetic substances such as ferrooxide labelled dextran. Scintillation proximity assays and fluorescence resonance energy transfer methods are also suitable. Magneto, luminescent and fluorescent methods, particularly chemiluminescent methods are preferred.

Where a detection method requires the addition of a cosubstrate, such as an oxidising agent, this will be added at a suitable stage, typically either simultaneously with the label or after suitable washing steps. Alternatively, species described herein may be “labelled” by means of their own mass. In such cases, these may be detected for example by Surface Plasmon Resonance (SPR), which technique is well known in the art and typically utilises SPR equipment from suppliers such as Biacore. Other physical methods of labelling include attachment to the “tip” of a force-microscope (e.g. an atomic force microscope (AFM) or chemical force microscope), whereby binding is detected by altered deflection of such a tip.

When used in any of the embodiments of the invention, the mimotopes and other peptides described herein may be synthetic peptides, formed by methods such as solid phase peptide synthesis, or may be formed by biosynthesis, such as by bacteria or by display on the surface of phage. Where the peptides (e.g. mimotopes) are biosynthesised, they may be secreted from the biosynthesising cell, phage, organism etc or may be displayed on the surface thereof. In the case of surface display, the peptides will typically be displayed on phage, for example as a conjugate attached to all or a part of the phage coat protein. Such peptides (e.g. mimotopes or conjugates of epitopic regions) may be used in the methods of the invention either by cleavage from the surface of the phage or by use of the whole phage, or that part or fraction of the phage which includes the displayed peptide. Where the peptide is to be used for generation of an immune response, the use of whole phage may have the advantage of provoking the immune system without the need to conjugate the peptide (mimotope etc.) to a separate immunogenic carrier.

In a further embodiment, the present invention provides a method for identifying specific binding partners for holoTC, having specificity for holoTC over apoTC of at least 40-fold, such as at least 50-fold, preferably at least 70-fold and most preferably 100-fold or more, comprising screening a library of potential specific binders with the above-described peptide mimotope, or constructs or conjugates thereof. Such a method will typically take the form of a “panning” assay, similar to that described using holoTC in Examples 1 and 2 below but has the advantage that the mimotope represents an epitope equivalent to epitope 4 of holoTC and therefore the majority of binders identified should possess specific binding for holoTC over apoTC. Suitable binders may comprise mAbs or fragments or constructs thereof, as described in Examples 1 and 2 below, but it will be clear that the same technique may be easily and routinely modified for the screening of other species, e.g. small organic molecules, aptamers, or oligopeptides (e.g. using peptide phage display libraries) in ways similar to those described in Example 4 below. Equally, such mimotopes and constructs thereof may be used in standard high throughput assay methods for identifying specific holoTC binders from synthetic peptide, oligonucleotide or small organic molecule libraries such as those commercially available.

Aptamers are a preferred type of sbp identifiable by screening against the above mimotopes. Where such DNA or RNA aptamers are identified they will preferably have the above specificity for holoTC over apoTC but remain of value when they have a specificity of at least 8-fold, preferably at least 10-fold and more preferably at least 15-fold.

In an additional embodiment, the present invention provides a method of inducing human-holoTC specific antibodies in a mammalian or preferably a non-mammalian (e.g. avian, piscine or reptilian) subject comprising administering the above-described mimotopes or immunogenic constructs and/or conjugates thereof (especially poly-hapten constructs thereof conjugated to suitable proteins, such as BSA) to said subject. Preferably said subject will be avian. Chickens are particularly suitable. The mimotope, construct or conjugate thereof will be immunogenic and will preferably present multiple copies of the mimotope for the purposes of inducing an immune response. Such a method will generally comprise administering a suitable antigenic construct of the above-describe mimotope, allowing a suitable period for an immune response to be generated, optionally administering one or more booster doses of the same or an alternative mimotope construct and extracting antibodies from the subject, either in the form of a polyclonal antibody extract, or preferably in the form of antibody-secreting cells, which may then be cultured using methods known in the art. In an embodiment of this method, human holoTCII or a fragment or construct thereof may be used for the initial immunisation of the non-mammalian subject, or for one or more of the booster immunisations, or both.

Specific binding partners for holoTC may also be identified by the use of peptide conjugates designed to express at least one of the epitopic regions I, II and III of epitope 4 described herein. Such peptides will be based upon the sequences from human holoTC;

-   I) Leu 39 to Lys 77 and Thr 265 to Lys 269 -   II) Ile 161 to Val 243 -   III) Arg 271 to Asp 297 (or preferably Lys 296).     Typically the regions will have the sequences indicated herein     supra.     A suitable peptide conjugate will thus typically have sequence I, II     or III, or fragments thereof, flanked by suitable linker sequences     to provide a desirable, 3-dimensional presentation of the region.     Preferably, all or parts of sequences I and II, sequences II and III     or sequences I and III will be present with linker sequences     between. More preferably, all three sequences I, II and III will be     present, in whole or part, at least once in the conjugate (in any     order) with linker sequences between and flanking sequences at one     or both ends. All linker and/or flanking sequences may have     cross-linkable points, such as cysteine residues, to allow control     over the 3-dimensional structure of the peptide conjugate. The     conjugates may also include mimotope sequences indicated above,     either in addition to the regions I-III or in place of all or part     of one or more of these regions. Suitable sequences may be     synthesised chemically, or more typically will be expressed in cells     or phage by methods analogous to those described herein for the     expression of mimotopes.

Where parts of any of regions I to III are used herein, these parts are preferably include some of the significant or preferably highly significant residues indicated herein supra. Preferably at least half of these residues are present in equivalent positions in the conjugates to their positions in the sequences given supra.

The peptide conjugates described above form a further embodiment of the invention as does their use in assays and identifying specific binding partners for holoTC. The peptide conjugates (and their constructs, labelled equivalents etc.) may thus be substituted for the mimotopes described herein in any suitable embodiment of the invention including methods for identifying specific binders, assay methods and methods for inducing immune reactions.

In a yet further embodiment, the invention provides an assay method for assaying for holoTC in a sample (e.g. a liquid sample of biological origin), said method comprising contacting said sample with a specific binding partner for holoTC and detecting the resultant conjugates of holoTC and the specific binding partner, wherein said specific binding partner has a specificity for holoTC relative to apoTC of at least 40-fold, preferably at least 50-fold, more preferably at least 70-fold (see, e.g., Example 6 below).

In this method, as is conventional in diagnostic assays, detection of the conjugate may be direct or indirect and quantitative, semi-quantitative or qualitative. Direct detection may thus be of a property of the conjugate that differs from that of the unconjugated holoTC and sbp (e.g. mass or radiation emission, absorption or scattering characteristics). Indirect detection may for example be by detecting conjugates formed in competition to the holoTC:sbp conjugates or by detecting a conjugate of a further ligand (e.g. a labelled ligand) and the holoTC:sbp conjugate or by separation of the conjugate from the sample, release of cobalamin and detection of the released cobalamin. Qualitative and semi-quantitative detection may involve determining whether holoTC is present in the sample above or below a predetermined concentration limit or at higher or lower concentrations than in some selected standard, e.g. so as to provide a simple indication as to whether the source of the sample does or does not suffer from holoTC deficiency. Desirably the assay will involve quantitative determination of holoTC content, and optionally also total TC and/or total cobalamin content. The specific binding partner used in this assay method may also and preferably will be a specific binding partner for a constrained peptide comprising the motif SX₁X₂YX₃WDX₄X₅X₆ where,

-   -   X₁=F, G, L     -   X₂=F, L, R     -   X₃=L, P, Q     -   X₄=M, Q, Y     -   X₅=D, F     -   X₆=M, R         or the motif         SFFYSLCYCW         and in particular may be a monoclonal antibody or fragment or         construct or a DNA/RNA aptamer with such specificity.         Furthermore, the holoTC sbp used in this method may, and         preferably will, be blocked in binding to holoTC by the prior         binding of certain other sbps with affinity for both apoTC and         holoTC. In a preferred embodiment, the specific binding partner         will be a monoclonal antibody with specificity for an epitope         overlapping with epitope 4 of TC as herein described or a         fragment or construct of such an antibody. In particular such an         antibody will be specific for epitope 4 and, for example, may         bind to any 1, any two or all three of regions I-II on TC, as         described above. Most preferably such antibody, fragment or         construct will be antibody 3C4 as herein described (or a         corresponding scFv) or a fragment or construct thereof. Suitable         specific binding partners may be identified by conventional         techniques based on selection for binding to TC, to the mimotope         or to an appropriate construct of regions I, II and/or III, as         herein described.

The holoTC sbp selection process will typically involve (i) selecting for the ability to bind to holoTC and/or the mimotope or construct thereof and (ii) deselecting candidate sbp's without the required specificity with respect to holoTC and apoTC. Desirably the sbp selection process also involves deselection of candidate sbp's which bind to haptocorrin or other serum proteins as otherwise the holoTC assay of the invention will require TC to be separated from HC or other blood proteins before being contacted with the sbp.

Accordingly, the holoTC sbp according to the invention is preferably an sbp which has a specificity for the said mimotope or construct, relative to apoTC of at least 40-fold, especially at least 50-fold, more preferably at least 70-fold. The holoTC sbp will also preferably have a selectivity for holoTC over the holo-forms of other cobalamin binding proteins (including, for example HC and intrinsic factor) of at least 50-fold, preferably at least 70-fold and more preferably 100-fold or more.

In the assay method of the invention, the holoTC specific binding partner may be used to capture holoTC, or may be used to identify holoTC previously captured by a secondary ligand.

Where the holoTC sbp is used to capture holoTC, it will generally be immobilised on a suitable substrate or immobilizable by use of an immobilising or precipitating agent as discussed above. Such substrates, agents and methods of immobilisation are well known in the art and include the methods described above. The holoTC captured by the holoTC specific binding partner may then be identified by contact with a secondary, optionally labelled ligand. Such a secondary ligand may be specific for holoTC but will generally be specific for TC (both apo- and holo-) and may bind to any epitope presented by the bound holoTC. Alternatively, the secondary ligand may be used to bind the captured holoTC and a labelled tertiary ligand with specificity for the secondary ligand. Such a tertiary ligand will then also be added, e.g. subsequently or simultaneously. Where detection is carried out by certain mass-sensitive or refractive index sensitive techniques such as SPR, the ligand may be “labelled” purely by its own mass.

A typical assay method utilising this “specific capture” technique comprises steps of:

contacting a liquid sample from a subject (such as a human patient or an animal, particularly a mammal) with an immobilised or immobilisable specific binding partner for holoTC to form a holoTC:sbp conjugate,

contacting the specific binding partner with a secondary ligand for TC or holoTC such that the secondary ligand binds to the bound holoTC to form a holoTC:sbp:secondary ligand conjugate,

separating the unbound secondary ligand from the holoTC:sbp:secondary ligand conjugate and optionally increasing the concentration of the holoTC:sbp:secondary ligand conjugate,

optionally releasing the holoTC:sbp:secondary ligand conjugate from a substrate and/or a holoTC: secondary ligand conjugate from the sbp, wherein the release is preferably into a volume of liquid less than the volume of the liquid sample,

optionally adding a cosubstrate or tertiary ligand to facilitate detection of the holoTC:sbp:secondary ligand conjugate or a holoTC:secondary ligand conjugate,

detecting holoTC:sbp:secondary ligand conjugate or a holoTC:secondary ligand conjugate, and

relating the detected amount of holoTC:sbp: secondary ligand conjugate or a holoTC:secondary ligand conjugate to the concentration of holoTC in the liquid sample to provide a quantitative, semi-quantitative or qualitative measurement of the holoTC present in the liquid sample, and optionally relating the holoTC present in the liquid sample to the presence or absence of cobalamin deficiency in the subject.

A preferred assay for holoTC described herein was constructed based on mAb 3C4 as the capture antibody and a non-overlapping, high-affinity antibody (Example 6.3) or aptamer (Example 14) as the detecting sbp. The accuracy of this assay was verified by comparison to a commercial assay for holoTC, HoloTC RIA® (Axis-Shield, Norway) (Example 7). The commercial assay is based on a different principle, namely solid-phase capture of total TC (apoTC+holoTC) and release of cobalamin bound in holoTC followed by a competitive binding radioimmunoassay (Ulleland et al, Clin Chem 48:526-32 (2002)). The assay method of the invention correlated well with the commercial assay with r=0.96.

The binding of holoTC specific sbps such as 3C4 will be blocked by the prior binding of sbps specific for certain overlapping epitopes present on holoTC and optionally also present on apoTC. Examples of these blocking sbps include sbps specific for epitope 5 as described herein and particularly monoclonal antibody TC2 as described below. Additional examples are ligands which bind to at least one of regions I to III as described herein. Blocking of holoTC binding by these TC specific sbps may be used to further characterise the holoTC specific sbps of the present invention.

In a preferred assay method, forming a further aspect of the invention, an (optionally labelled) holoTC sbp is used as a detection ligand for holoTC previously, simultaneously or subsequently captured by an immobilised or immobilisable secondary ligand. Such secondary ligand may also be specific for holoTC, whereby to increase the specificity of the assay, but more preferably will bind both holoTC and apoTC. Preferably, such secondary ligand will have an affinity for TC which is greater than that of the holoTC sbp. Such an affinity may for example be at least 10⁸ M⁻¹, or at least 10⁹ M⁻¹ but is preferably at least 10¹⁰ M⁻¹ and most preferably 10¹¹ M⁻¹ or greater. Especially preferably the TC capture ligand is one which does not cause a significant reduction in the specificity of the holoTC sbp for holoTC over apoTC. More preferably, the capture ligand should not cause a significant reduction in the affinity of the holoTC sbp for holoTC. Such preferred capture ligands include those which bind to an epitope which does not overlap with the epitope to which the holoTC sbp binds, and preferably does not bind in a way which causes any change in the conformation of the epitope to which the holoTC sbp binds. Preferred capture ligands are those which do not cause the specificity of the holoTC sbp to drop below at least 40-fold, preferably at least 50-fold, especially at least 70-fold. Generally preferred capture ligands will not bind to any of regions I to III as described herein.

A typical assay according to this embodiment of the invention may comprise the steps of:

contacting a known volume of liquid sample from an animal subject (particularly a mammal and preferably a human patient) with a capture ligand (such as an immobilised or immobilisable mAb, scFv or DNA/RNA aptamer) having specificity for TC, whereby to form a TC:capture ligand conjugate,

optionally separating a fraction containing substantially all of the TC:capture ligand conjugate from a fraction containing substantially no TC:capture ligand conjugate, optionally in a known reduced volume,

contacting said TC:capture ligand conjugate with a (preferably labelled) holoTC specific binding partner (such as a mAb, aptamer, specific binding peptide etc, as described above, particularly mAb 3C4 or a corresponding scFv) to provide a sbp:holoTC:capture ligand conjugate,

optionally separating the unbound holoTC sbp from the sbp:holoTC:capture ligand conjugate,

optionally adding a cosubstrate or tertiary ligand to facilitate detection of the bound holoTC sbp,

detecting the bound holoTC,

relating the detected bound holoTC sbp to the volumes to provide a quantitative, semi-quantitative or qualitative indication of the holoTC present in said liquid sample, and optionally relating the holoTC present in the liquid sample to the presence or absence of cobalamin deficiency in the subject.

The liquid sample may if desired be pretreated to increase the TC concentration therein and/or to remove or deplete HC (especially holoHC) and if desired albumin therein. This might typically involve application of a sample to a substrate to which HC or TC binds, separation of substrate and liquid phase and (where the substrate binds TC) release of TC from the substrate to form a new, preferably known lower volume, liquid sample. This HC depletion is particularly important when the final holoTC detection step involves detection of cobalamin released from the holoTC.

The steps of these methods may be appropriately re-ordered, in ways which will be obvious to those of skill in such assays, for example to allow the contact of the holoTC specific binder with the holoTC prior to the capture of the TC with the capture ligand.

Suitable capture ligands for use in the above assay method of the present invention bind one or more epitopes of TC other than the epitope (such as epitope 4 as herein described) bound by any holoTC specific binder. Further, the capture ligand should preferably bind to an epitope not overlapping with any such holoTC specific epitope. As described above, at least 7 epitopes of TC have been identified, of which at least 4 do not overlap with holoTC specific epitope 4. Preferably, and particularly when the liquid sample is contacted with the capture ligand prior to contact with any holoTC specific binder, the capture ligand should bind to an epitope or in such a fashion that the binding of any holoTC specific binder is neither inhibited nor made less holoTC specific.

The capture ligand should preferably bind in such a way that no substantial change is thereby made to the configuration of any holoTC specific epitope. These will generally not bind to any of regions I to III as described herein.

Monoclonal antibodies having no significant inhibitory effect on the binding or specificity of mAb 3C4 have been identified as described in the Examples below. Such antibodies are highly suitable for use as capture ligands in an assay method of the invention. In particular, ligands binding to epitope 2 as herein described are highly suitable for use as capture ligands in assay methods of the invention. Monoclonal antibody ligands to epitope 2 have been identified and are highly suitable. Most preferred capture ligands, however, are small ligands (such as scFvs), preferably with high affinity for TC. Small ligands may be bound more concentratedly a substrate and thus provide a greater concentration effect, allowing an increase in assay sensitivity. Antibody fragments, small peptide binders (particularly constrained peptides), nucleic acid oligomers (e.g. aptamers) and small organic molecules are all preferred small ligands. Fragments of mAbs (and scFvs) raised against epitope 2 are most preferred. Constructs comprising multiple repeats of such small ligands, which may be joined by chemical bonds and/or comparatively small linkers, are also suitable.

Where holoTC present in a liquid sample is captured by a TC specific capture ligand and contacted with a (preferably labelled) holoTC specific ligand for the purposes of detection of holoTC, the captured TC may (previously, simultaneously or preferably subsequently) be contacted with a TC detection ligand for the purposes of determining the total TC captured by the capture ligand and/or an apoTC detection ligand for the purposes of determining the apoTC captured by the capture ligand. The TC and/or apoTC content thereby determined may be related to the TC and/or apo TC content of the fluid sample, may be used to determine the holoTC saturation level of the TC, or may be used as an internal standard or verification by comparison with the determined quantity of holoTC.

Suitable TC detection ligands are preferably labelled specific binding partners for TC such as mAbs, aptamers, etc as described above which are specific for an epitope of TC not overlapping with either the epitope bound by the capture ligand (such as epitope 2 as described herein) or with the epitope bound by any holoTC specific binding ligand (e.g. epitope 4 as herein described). Suitable TC detection ligands also include the mAbs raised against epitopes 1, 3, 6 and 7 as described herein, and fragments and constructs thereof, optionally labelled in ways well know in the art and described above.

The labelling of any TC detection ligand may be the same or different from the labelling of any holoTC specific binder. Where methods such as SPR are used for detection, both labels will be detected by mass, usually sequentially. Where methods such as photometric detection (fluorescence, luminescence etc) are used, the labels will preferably be distinguishable (e.g by excitation and/or detection wavelength) and may be detected simultaneously or sequentially.

Suitable apoTC detection ligands may be ligands with specific binding affinity for apoTC over holoTC (e.g. cobalamin or cobalamin conjugates, optionally conjugated to a signal giving moiety) but are preferably ligands binding an epitope overlapping with the epitope bound by a holoTC specific binder (such as one of regions I to III). An assay utilising such a ligand will typically comprise the steps of binding captured TC from a liquid sample with a holoTC specific binder, subsequently contacting the captured TC with an apoTC detection ligand specific for an epitope present on both apoTC and holoTC but overlapping with the epitope bound by the holoTC specific binder and detecting the holoTC specific binder and the apo detection ligand. Such an apoTC detection ligand will be substantially prevented from binding to holoTC by the presence of pre-bound holoTC specific binder but will bind freely to the corresponding epitope on apoTC thereby providing a signal representing the amount of apoTC present in the fluid sample.

As with any TC detection ligand, the labelling of any apoTC detection ligand may be the same or different from the labelling of any holoTC specific binder. Where methods such as SPR are used for detection, both labels will be detected by mass, usually sequentially. Where methods such as photometric detection (fluorescence, luminescence etc) are used, the labels will preferably be distinguishable (e.g by excitation and/or detection wavelength) and may be detected simultaneously or sequentially. Preferably sequential detection will be used when the method used for detecting two ligands provides indistinguishable signals and simultaneous detection will be used when the signals from two ligands can be distinguished.

A further, highly preferred assay method of the invention utilizes mAb 3C4 as the detecting antibody (Examples 6 and 17). Such an approach has at least two advantages: (i) using as capture sbp (e.g. antibody) a mAb or aptamer with higher affinity for TC allows virtually all TC in a sample to be captured and concentrated; (ii) using mAb 3C4 as the detecting antibody increases the functional affinity of mAb 3C4. The KD for 3C4 was estimated at >100 nM, however, because monoclonal antibodies are divalent, making use of both binding sites decreases the off-rate and thus also decreases the functional KD (avidity). In the case of mAb 3C4, the off-rate was decreased from 2×10⁻³ s⁻¹ to 2×10⁻⁴ s⁻¹ when mAb 3C4 was used as detecting antibody rather than capturing antibody. As discussed above, a suitable capture antibody should preferably be a mAb that does not compromise the affinity or the specificity of mAb 3C4 for holoTC. We found that antibodies to epitope 2 best fulfilled these requirements. Although aptamer b974-3t1 as described herein overlapped partially with mAb 3C4 (see 11 and Example 17) this overlap was not sufficient to compromise the affinity or the specificity of mAb 3C4 and sufficient affinity was retained to fulfill the requirements of the assay (see Examples 16 and 17).

Simultaneous measurement of holoTC and apoTC in the same assay was also demonstrated utilizing antibodies directed to epitopes 4 and 5 (Examples 8 and 9). These epitopes overlap fully on holoTC while epitope 4 is not present on apoTC. Thus, by adding to a sample containing a mixture of apoTC and holoTC, first mAb 3C4, binding to epitope 4, and then mAb TC2, binding to epitope 5 and having the antibodies conjugated to different signal giving ligands, both apoTC and holoTC may be directly measured in the same sample. Alternatively, the apoTC and holoTC may first be captured and concentrated by a non-overlapping ligand (especially aptamer or monoclonal antibody), preferably of epitope 2 binding, prior to detection. Where apoTC is detected due to the “blocking” of one epitope present on apo-TC and holo-TC by binding to an epitope present only on holoTC (such as epitope 5 being blocked by binding to epitope 4), such blocking need not be complete. Providing the holoTC binding under certain conditions blocks a known proportion of the binding sites or that the number of sites revealed is insignificant in comparison to the total apoTC level then useful data can be generated. Preferably greater than 80% of the sites on holoTC will be blocked by the holoTC binding, more preferably 90% or more and most preferably at least 95%.

Further, simultaneous measurement of holoTC and total TC in the same assay was demonstrated utilizing antibodies directed to epitopes 4 and 6 (Example 10) and aptamer b974-3t1 (FIG. 12 Example 17). These epitopes do not overlap and neither one overlaps with epitope 2. Thus, by adding to a sample containing a mixture of apoTC and holoTC, first mAb 3C4, binding to epitope 4, and then mAb 3C12, binding to epitope 6 and having the antibodies conjugated to different signal giving ligands, both apoTC and total TC may be directly measured in the same sample. Simultaneous measurement of holoTC and total TC in the same assay can also be accomplished by use of b974-3t1 as capture sbp and detecting holoTC and total TC using mAb 3C4 (epitope 4) and mAb 4-7 (epitope 2B) respectively (see Example 17).

In a further aspect the invention also provides a kit for use in an assay method according to the invention, said kit comprising an optionally labelled or immobilized specific binding partner for holoTC having a specificity for holoTC over apoTC of at least 40-fold (e.g. 50-fold or more); optionally and preferably an optionally labelled or immobilized TC binding ligand; optionally a plurality of holoTC solutions of known concentration; and optionally instructions for the performance of said assay method.

The present invention will be described further below by reference to the following non-limiting Examples and by reference to the accompanying drawings in which;

FIG. 1 a represents the SPR “sensogram” showing the binding of mAb 3C4 to holoTC (871 RU) and absence of binding to apoTC (0 RU) immobilised to a chip by a mAb specific for epitope 2;

FIG. 1 b is equivalent to FIG. 1 with mAb 5H2 (epitope 2) as capture ligand—the binding of mAb 3C4 to holoTC (185 RU) and absence of binding to apoTC (0 RU) are shown;

FIG. 2 represents the affinity and specificity of various antibodies described herein for native holoTC and apoTC;

FIG. 3 a represents an “epitope map” of TC as generated by the epitope mapping method described herein;

FIG. 3 b represents a modified “epitope map” of TC as generated by the epitope mapping method described herein;

FIG. 3 c represents a further modified “epitope map” of TC as generated by the epitope mapping method described herein;

FIG. 4 a represents the results of applying standard solutions of holoTC to an assay method for holoTC as described herein utilising antibody 3C4 as capturing antibody;

FIG. 4 b represents the results of applying standard solutions of holoTC to an assay method for holoTC as described herein utilising antibody 3C4 as capturing antibody and using absorbance detection;

FIG. 4 c represents the results of applying standard solutions of holoTC to assay methods for holoTC as described herein utilising holoTC specific single chain antibodies as capturing antibodies;

FIG. 4 d represents the results of applying standard solutions of holoTC to an assay method for holoTC utilising antibody 3C4 as capturing antibody and using luminescence detection;

FIG. 5 a represents a standard curve generated from standard mixtures of holoTC and apoTC in an assay method of the invention, showing the amount of mAb 3C4 as detection ligand bound to holoTC on a capturing antibody;

FIG. 5 b is an equivalent curve to 5 a showing the amount of mAb 3C4 as detection ligand bound to holoTC on a capturing antibody, wherein the capturing antibody is mAb TC7;

FIG. 6 a represents a comparison between an assay method as described herein in and a commercial holoTC assay;

FIG. 6 b represents a further comparison between an assay method as described herein in and a commercial holoTC assay;

FIG. 7 a represents the binding of antibodies specific for epitope 4 (3C4) and epitope 5 (TC2) sequentially to immobilised mixtures of holoTC and apoTC;

FIG. 7 b represents the same binding as seen in FIG. 7 a but the capture ligand is mAb TC7.

FIG. 8 represents a standard curve of TC cobalamin saturation showing the relative binding to epitopes 4 (by 3C4) and 6 (by 3C12) for holoTC and apoTC immobilised in known proportions;

FIG. 9 represents the binding of antibodies specific for epitope 4 (3C4) and epitope 6 (3C12) sequentially to immobilised mixtures of holoTC and apoTC;

FIG. 10 represents the inhibition of binding between TC and various of the mAbs described herein caused by the polysaccharide heparin at various concentrations.

FIG. 11 represents an SPR “sensorgram” showing the binding of, aptamer b974-3t1 to holoTC immobilised to a chip by mAb 3C4 (top line). No response is seen (bottom line) when apo-TC is used in place of holo-TC because mAb 3C4 does not recognise (and therefore does not capture) apo-TC;

FIG. 12 represents the sequential binding of antibodies specific for epitope 4 (3C4) and epitope 2B (4-7) to holo-TC and apo-TC captured by aptamer b974-3t1 (down arrows indicate time of injections). No response is seen when 3C4 is injected over captured apo-TC because epitope 4 is not present;

FIG. 13 a represents the structure of human TC showing epitope 4;

FIG. 13 b represents the structure of human TC showing the heparin binding site;

FIG. 14 shows a schematic of the various epitopes identified on holoTC;

FIG. 15 a represents the interaction between the paratope of 3C4 and the preferred epitope regions of holoTC; and

FIG. 15 b represents the interaction between the extended paratope of 3C4 and the epitope regions of holoTC.

EXAMPLE 1 Development of Mouse Monoclonal Antibodies Specific for Human Transcobalamin and Human Holotranscobalamin

1.1) Immunization

BALB/c female mice were injected i.p. with 20 μg of recombinant human holoTC mixed with AdjuPrime Immune modulator (Pierce, Ill., USA), followed by two booster injections of 20 μg at four week intervals.

1.2) Fusion

Four days after the final boost, spleens were removed and splenocytes fused to the HAT (Hypoxanthine, Aminopterin, Thymidine; Sigma) sensitive plasmacytoma OUR1 (a subclone of X63-Ag8.653) using PEG (Boehringer Mannheim, Germany). Fusion products were plated over 5×96F trays (Nunc) in the presence of HAT in culture medium (DMEM/Ham's F12 (Invitrogen) plus 10% CPSR3 (Sigma). Fusions were fed after 1 week with culture medium containing HT (Sigma).

1.3) Primary Screening

After two weeks, medium from hybridomas was screened using a solid phase capture assay. The cell media were mixed with 10 μL of 1% (w/v) suspension of 1 μm magnetizable beads coated with a sheep anti-mouse IgG antibody (Merck-Estapor, France) and kept at ambient temperature for 1 h. The magnetizable beads with bound mouse monoclonal antibodies were isolated by using a magnet, and washed four times with 1 mL phosphate buffer, pH 7.2, 0.15 M NaCl and 1 mg/mL bovine serum albumin. Washed beads were resuspended in 100 μL of pooled human serum (Scantibodies, USA) which had been pretreated with 57Co-labelled cobalamin (ICN, USA) to convert apoTC in the serum into 57Co-labelled holoTC. The mixtures were kept at ambient temperature for 30 min and beads isolated by using a magnet. The radioactivity associated with the beads was counted in a gamma counter.

1.4) Cloning

Wells positive for anti-TC antibodies were cloned by limiting dilution over 96 wellF trays (Nunc), pre-seeded with Balb/c peritoneal feeder cells (10,000 per well). Positive clones were selected, and recloned until 100% of the subclones were producing specific antibody. Cell stocks were frozen in liquid nitrogen, in CPSR3 (Sigma) containing 10% DMSO (Sigma).

1.5) Secondary Screening

Antibodies from cell media were isolated on magnetizable beads as described above. Ten μL of the antibody coated beads were mixed with serum prelabelled with 57Co, as described above, in the presence of increasing concentrations of recombinant, human apoTC or holoTC.

Murine chimeric cell lines prepared as above and expressing the following antibodies were deposited at the European Collection of Cell Culture (ECACC), Porton Down, Salisbury, Wiltshire, SP4 0JG, UK in the name of Axis-Shield ASA:

Antibody Epitope Accession No. Date of deposit 3C4 (3CY) 4 02110741 7 Nov. 2002 TC2 5 02110742 7 Nov. 2002 3C12 6 03090501 5 Sep. 2003 TC7 2 03090502 5 Sep. 2003 TC4 3 03090503 5 Sep. 2003 5H2 2 03090504 5 Sep. 2003

When used herein, the above epitope numbers are used as indicating the epitopes of TC and/or holoTC which are bound by the corresponding antibodies.

EXAMPLE 2 Affinities and Specificities of Selected Monoclonal Antibodies

The affinities and specificities of the monoclonal antibodies were evaluated by surface plasmon resonance using a Biacore® instrument (Biacore, Sweden).

2.1) Immobilization of rabbit Anti-mouse IgG Polyclonal Antibody or Mouse Monoclonal Antibodies on Dextran Coated CM5 Chip

The carboxylated surface of the a dextran coated CM5 chip (Biacore, Sweden) was activated according to protocol supplied by the manufacturer. In short 0.05M N-hydroxysuccinimide (NHS)/0.2 M N-ethyl-N′-[3-(dimethylamino)propyl]carbodiimide hydrochloride (EDC), was injected over the carboxylated chip at 10 μL/min for 7 min, then 50 μg/mL rabbit anti-mouse IgG polyclonal antibody in 10 mM acetate buffer, pH 5.0 is injected at 10 μL/min for 7 min, and finally the chip is blocked by injection of 1 M ethanolamine at 10 μL/min for 7 min. Immobilization of mouse monoclonal antibodies on the dextran coated chip was performed in the same way.

2.2) Binding of Mouse Monoclonal Antibodies to Rabbit Anti-mouse IgG Coated Dextran Chip

Mouse monoclonal antibodies which were not available in purified form and thus could not be directly immobilized on to the dextran coated chip (Example 2.1) were bound to the rabbit anti-mouse IgG coated dextran chip. Antibodies were diluted to circa 50 μg/mL in 0.01 M HEPES buffer, pH 7.4, 0.15 M, 0.003 M EDTA and 0.005% (v/v) Surfactant P20 (HBS-EP) and injected over the chip at 5 μL/min for 3 min. The binding of monoclonal antibody was followed in real time and the amount of mass bound was recorded in RU (Refractive units) in the sensorgram.

2.3) Binding of apoTC and holoTC to Mouse Monoclonal Antibodies

ApoTC and holoTC were diluted in HBS-EP to different concentrations and injected over the chip with immobilized mouse monoclonal antibody at 5 μL/min for 3 min. The on and off rates of binding were recorded for different concentrations of apoTC and holoTC and the affinity constants estimated (Table 1). Typical sensograms generated by this method is shown in FIGS. 1 a and 1 b.

2.4) Epitope Mapping

The epitope specificity pattern was characterized with a panel of 17 mAb to create a functional epitope map (Table 1). Antibodies were bound pairwise to holoTC or apoTC. A first mAb was either immobilized onto the dextran coated chip as described in Example 2.1 or bound to the anti-mouse IgG chip. In the latter case, 1:10 diluted mouse serum was then injected in order to saturate excess binding sites on the anti-mouse IgG chip. HoloTC or apoTC was injected and bound to the first mAb followed by the second mAb. All mAb were combined in all possible permutations and mAb that could not bind concurrently or whose binding were compromised by the first antibody were considered fully and partially overlapping, respectively. Based on overlap data an epitope map was then constructed (FIG. 3 a). This epitope map was then expanded to that shown in FIG. 3 b on the basis of the results of Example 17 below. The epitope map was then further expanded to accommodate the epitopic regions described in Examples 18 and 19, as shown in FIG. 3C. Table 2 depicts data for antibodies binding to each type of epitope.

Monoclonal antibodies to epitopes 4 and 5 could be separated only by their differential binding to apoTC. Whereas the epitopes overlapped completely on holoTC, they were fully separated on apoTC because epitope 4 was not (or was only very weakly) present on apoTC.

TC is known to have a binding site for the endogenous polysaccharide heparin. The inhibitory effect of unfractionated heparin of mean molecular weight 12000 Da (Sigma) on the interation between holoTC and various mabs was also tested. As indicated in FIG. 3 b, the heparin binding site was found to overlap strongly with epitope 6, somewhat with epitope 4 and to a lesser degree with epitope 2A.

Further experiments using a purified preparation of the epitope 6 antibody, 3C12, indicated that this epitope partially overlaps with epitopes 1 and 2.

Blood samples from TC deficient patients having an intra exonic cryptic splice site in the TC gene giving rise to a 27 amino acid deletion (117-144) in the expressed TC, were kindly provided by Dr. Fares Namour. The mutated TC was recognized by mAb 3-9 but not by mAb 2-2, indicating that epitope 2 overlaps significantly with the sequence 117-144. The common TC polymorphism P259R did not compromise recognition by any of the antibodies.

TABLE 1 Epitope mapping of human TC Name of KD of mAb#1 mAb overlapping mAb#1 (nM) with mAb#1 1-9* 5-10 5-18, TC4 1-12* 5-10 2-6, 3-5, 3-9, Q2-13 2-2* 0.08 3-11, 4-7, 5H2, TC7 2-6* <1 1-12, 3-5, 3-9, Q2-13 3-5* 1-5  1-12, 2-6, 3-9, Q2-13 3-9* 0.04 1-12, 2-6, 3-5, Q2-13, (Q2-2) 3-11* 0.08 2-2, 4-7, 5H2, TC7 4-7* 0.17 2-2, 3-11, 5H2, TC7 5-18* 10-100 1-9, TC4, (3C4, 3C12, TC2) Q2-2* 5-10 (3-9) Q2-13* 5-10 1-12, 2-6, 3-5, 3-9, (TC2) 3C4 >100 TC2, (5-18) 3C12 5-10 (5-18) 5H2 >100 2-2, 3-11, 4-7, TC7 TC2 1-5  3C4, (1-12, 5-18, Q2-13) TC4 5-10 1-9, 5-18 TC7 10-100 2-2, 3-11, 4-7, 5H2 *Antibody from State University of New York.

Antibodies in parenthesis were partially overlapping with mAb #1

TABLE 2 holo/apo Kd¹ Specificity mAb Isotype Epitope (nM) (-fold) 3-9* IgG1 1 0.04 1 5H2 IgG1 2A² >100 4 TC7 IgG2a 2B² 10-100 1 TC4 IgG1 3 5-10 1 3C4 IgG1 4 >100 >70³    TC2 IgG1 5 1-5  1 3C12 IgG1 6 5-10 1 Q2-2* n.d. 7 5-10 1 *Antibody from State University of New York (Ulleland et al, Clin Chem 48: 526-32; (2002)), included for comparison purposes. ¹Kd values for holoTC. ²Epitope 2 may be subdivided into two subgroups, A and B, based on the results obtained with heparin (see above) and aptamer b974-3t1 (see Example 15 and Table 11). ³Because of the high Kd value for apoTC and traces (<1%) of holoTC in the apoTC preparation, it was not possible unambiguously to determine if the specificity was better than 70-fold.

EXAMPLE 3 Specificities of Monoclonal Antibodies in Serum

3.1) Immobilization of Monoclonal Antibodies on Goat Anti-mouse IgG Coated Magnetic Particles

Monoclonal antibodies diluted to circa 7 μg/mL in PBS, pH 7.4 containing 1 mg/mL BSA were mixed with 0.2% (w/v) rabbit anti-mouse IgG coated magnetic particles of diameter 0.8 μm (Merck Eurolab, France) for 1 h at ambient temperature. Beads were then isolated by using a magnet, washed three times with cold PBS and resuspended in PBS, containing 1 mg/mL BSA.

3.2) Binding of Native holoTC to Immobilized Monoclonal Antibodies

10 μL of monoclonal antibodies bound to magnetic beads (3.1) were mixed with 100 μL serum pretreated with 57Co-cobalamin (circa 50 fmol; ICN, USA) to convert all apoTC to 57Co-labelled holoTC and allowed to stand at ambient temperature for 1 h. Beads were then sedimented using a magnet, washed twice with cold PBA containing 1 mg/mL BSA and, after sedimentation by a magnet, counted in a gamma counter.

3.3) Binding of Native apoTC to Immobilized Monoclonal Antibodies

10 μL monoclonal antibodies bound to magnetic particles (3.1) were mixed with 100 μL serum and allowed to stand at ambient temperature for 1 h. Beads were then sedimented by using a magnet, and the supernatant saved. The beads were washed twice with cold PBA containing 1 mg/mL BSA, and, after sedimentation by a magnet, resuspended in 100 μL PBS containing 1 mg/mL BSA and 57Co-cobalamin (circa 50 fmol) and kept at ambient temperature for 1 h, after which the beads were sedimented by a magnet, washed twice with PBS containing 1 mg/mL BSA and counted in a gamma counter. To estimate the amount of apoTC remaining in the serum supernatants these were treated with 57 Co-cobalamin (circa 50 fmol) and then with 10 μL of magnetic beads coated with a high affinity anti-TC antibody, which has the capacity to bind virtually all TC in a serum sample (see Ulleland et al, Clin Chem 48:526-32; 2002). The beads were sedimented using a magnet and counted in a gamma counter.

3.4) Specificity of Monoclonal Antibodies for Native holoTC

The binding of holoTC and apoTC by the monoclonal antibodies were compared to that of a monoclonal anti-human TC antibody which had been previously determined to quantitatively remove holoTC and apoTC from serum (see Ulleland et al, Clin Chem 48:526-32; (2002)). The results are depicted in FIG. 2. The monoclonal antibody specific for epitope 4 (mAb 3C4) bound holoTC but no detectable amounts of apoTC. The antibodies to the other epitopes bound both holoTC and apoTC.

EXAMPLE 4 Biopanning of Phage Display Peptide Library with mAb 3C4

Disulfide cyclized 13 mer peptide libraries (Cosmix Molecular Biologicals GmbH, Germany) were panned; however, any peptide library of sufficient variability (>10⁸ variants) and preferably constrained to decrease flexibility might be used.

4.1) Coupling Procedure for mAb 3C4

20 μL of Dynal® Carboxybeads were washed three times in 1 mL PBS containing 0.005% Tween 20 (PBST). Activation of the beads was carried out in 100 μL 0.5M EDC/0.1M NHS for 10 min at room temperature. 4 μg of mAb 3C4 was immobilized to the beads in 100 μL acetate buffer, pH 4.0 for 45 min at room temperature. Blocking was performed with 100 mM ethanolamine in PBS. After blocking the beads were washed three times in PBS.

4.2) Panning Procedure

About 10¹² packaged phagemids of each library were incubated for 1 h with 20 μL 3C4-coated beads. As a control 20 μL carboxybeads without target was used. After incubation beads were washed with PBST. Elution of packaged phagemids was performed with Glycine-HCl, pH 2.2 (Gly) for 10 min immediately followed by neutralization, with Tris-HCl, pH 8.0 (Tris). Amplification and purification of bound phage particles were carried out according to standard protocols. Basically, 1 mL phage is transferred to 1 mL of log-phase E. Coli cells. Incubate for 30 min without shaking and then for 30 min with shaking at 37 C. Centrifuge at 1000 g for 10 min and resuspend in 1 mL 2TY-medium (16 g tryptone, 10 g yeast extract and 5 g NaCl per L, pH 7.0, sterilize) and plate bacteria on a large square plate containing 100 μg/mL ampicillin and 1% glucose. Incubate plates over night at 30 C. Next day add 10 mL 2TY and loosen cells from plates. Add 100-500 μL to 50 mL 2TY, containing 100 μg/mL ampicillin, 1% glucose and grow at 37 C to an OD600 of about 0.5, which takes about 2 h. Add 10-fold excess of helper phage, e.g. M13 phage, and incubate 30 min at 37 C without shaking and then 30 min with shaking. Centrifuge 1000 g and resuspend cells in 50 mL 2TY containing 100 μg/mL ampicillin and 50 μg/mL kanamycin. Incubate over night at 30 C, spinn at 2500 g for 15 min, and transfer supernates to fresh tubes and add ⅕ volume 20% PEG, 2.5 M NaCl. Incubate on ice for 1 h, centrifuge 2500 g for 15 min, resuspend pellet in 1 mL PBS, spinn at 12000 g for 2 min to remove residual bacteria and transfer supernates to fresh tubes and use 100 μL for next round of selection. Quantitative enrichment was observed already after the second round of panning, and clones from the second and third rounds were sequenced. Several clones occurred more than once and in all seven different sequences were obtained, forming two motifs:

Motif 1: CSX₁X₂YX₃WDX₄X₅X₆CS Where CS is part of the framework, and

-   -   X₁=F, G, L     -   X₃=L, P, Q     -   X₅=D, F     -   X₂=F, L, R     -   X₄=M, Q, Y     -   X₆=M, R         Motif 2:         CSFFYSLCYCWCS         4.3) Screening ELISA

Microtitre plates were coated with 100 μL, 1 μg/mL mAb 3C4 or unrelated control antibody in PBS over night at 4 C. Remaining binding sites were blocked with 20 mg/mL bovine serum albumin (BSA) in PBS for 1 h. Some wells were only coated with BSA. Monoclonal packaged phagemids were added at a concentration of 10¹⁰ to 10⁸ cfu per well in PBS and incubated for 1 h. Preparations of packaged phagemids were centrifuged to remove aggregates. Wells were washed 6 times with PBS containing 0.1% Tween-20 and 3 times with PBS. For detection of bound phages 100 μL of horse-radish peroxidase (HRP) conjugated anti-M12 antibody (e.g. Pharmacia) diluted 1/5000 in PBS was added to each well and incubated for 1 h at ambient temperature. ELISA plates were washed 5 times with PBS containing 0.1%

Tween-20 and 3 times with PBS. The chromogenic substrate o-Phenyldiamine in citric acid, pH 4.0 supplemented with H₂O₂ was added and the color generating reaction was stopped after 2-5 min by addition of 2 M H₂SO₄. Results are shown in Table 3.

TABLE 3 Seq ELISA (absorbance units) ID Amount of anti-TC Control Phagemid No. Sequence phagemid mAb mAb BSA CS1–2p 10 CSLFYLWDQDR CS 10¹⁰ 0.287 0.228 0.327 10⁹ 0.224 0.199 0.277 10⁸ 0.245 0.188 0.264 CS1–6p 11 CSFRYLWDQDR CS 10¹⁰ 1.065 0.203 0.275 10⁹ 0.664 0.172 0.270 10⁸ 0.406 0.173 0.254 CS1–9p 12 CSGLYPWDMFR CS 10¹⁰ 0.769 0.213 0.221 10⁹ 0.539 0.204 0.220 10⁸ 0.259 0.209 0.216 CS1–11p 13 CSFRYQWDMFR CS 10¹⁰ 0.645 0.242 0.304 10⁹ 0.559 0.258 0.278 10⁸ 0.348 0.252 0.268 CS1–29p 14 CSGLYPWDYFM CS 10¹⁰ 0.335 0.148 0.141 10⁹ 0.136 0.147 0.147 10⁸ 0.156 0.125 0.127 CS1–31p 15 CSFFYSLCYCW CS 10¹⁰ 0.298 0.125 0.112 10⁹ 0.165 0.118 0.114 10⁸ 0.152 0.116 0.109

The amino acids depicted in italics are conserved and part of the framework of the library.

EXAMPLE 5 Evaluation of Specificity of Selected Phages by Surface Plasmon Resonance

Antibodies were covalently immobilized on a dextran coated CM5 chip as described in Example 2. Phages were diluted 10-fold in HBS-EP and injected at 10 μL/min for 3 min. The amounts of phagemid bound was recorded in real time and expressed in response units (RU). To evaluate blocking by holoTC, 1 μM of holoTC was injected at 10 μL/min for 5 min prior to the injection of phagemids at 10 μL/min for 3 min. Inhibition was computed as the number of RU of phagemid bound to 3C4 with pretreatment with holoTC divided with the number of RU bound without pretreatment, times 100.

TABLE 4 Binding of phagmids to mAb 3C4 and blocking by 1 μM holoTC. Phage Block by bound holoTC Inhibition Phagemid (RU*) (RU) (%) CS1-2p 4  n.d.¹ n.d. CS1-6p 24 3 88 CS1-9p 35 1 87 CS1-11p 32 0 100  CS1-29p 20 3 85 CS1-31p 42 5 88 CS1-37p 0 n.d n.d. *RU, response units. ¹n.d., not done.

TABLE 5 Binding of phagemids to anti-TC antibodies having different epitopes on TC. Phagemid CS1-6 CS1-11 CS1-31 mAb epitope (RU) (RU) (RU) 3-9* 1 0  0  0 5H2 2 0 — — TC4 3 0 — — 3C4 4 45 32 42 TC2 5 1 — — 3C12 6 0 — — *Antibody from State University of New York (Ulleland et al, Clin Chem 48: 526-32; (2002)). Used for comparison purposes.

EXAMPLE 6 Assay for Direct Measurement of holoTC

6.1) Iodination of Monoclonal Antibody 3-9

mAb 3-9 was labelled with 125I using IODO-GEN® pre-coated iodination tubes (Pierce, USA) and a protocol supplied by the manufacturer. In short, the tube containing 50 μg evaporated IODO-GEN® iodination reagent is rinsed with 1 mL 0.025M Tris, 0.4 M NaCl, pH 7.4 (Tris). Then 50 μg antibody in Tris is added and incubated for 5 min at ambient temperature. 50 μL 10 mg/mL tyrosin in Tris is added and incubated 5 min and then the mixture is chromatographed on a column of NAP-5 equilibrated with 10 mL 0.01M phosphate buffer, 0.3 M NaCl, 0.01% merthiolate, and 1 mg/mL BSA, pH 7.3.

6.2) Immobilization of holoTC Specific mAb 3C4 on Magnetic Beads

4 mg Estapor® EMI-100/40, 0.83 μm magnetic beads were washed three times in 4 mL ice cold 0.05 M MES buffer, pH 6.0 (MES). Activation was carried out in 42 mL 0.063 M EDC/0.033 M sulfo-NHS for 15 min at ambient temperature. The activated beads were rinsed two times in 30 mL MES. 2.8 mg mAb 3C4 was immobilized on the beads in 6.8 mL MES for 2 h at ambient temperature. Blocking was performed with 5 mg/mL BSA, 0.05 M ethanolamine in PBS. After blocking beads were washed three times in PBS and resuspended in 40 mL PBS.

6.3) Assay for holoTC Using mAb 3C4 as Capture Antibody

800 μL of serum was mixed with 800 μL PBS and added 50 μL of mAb 3C4 coated magnetic beads. After incubation at ambient temperature for 1 h, beads were separated by using a magnetic rack, washed three times with 400 μL PBS containing 1 mg/mL BSA (PBA), and resuspended in 400 μL PBA. Then, 50000 cpm of 125I-labelled mAb 3-9 was added and incubated for 1 h at ambient temperature. Beads were separated on the magnetic rack, washed three times with 400 μL PBA and counted in a gamma counter. The standard curve was constructed using calibrators made up of recombinant, human holoTC, and processed in parallel with the samples. A typical standard curve is seen in FIG. 4.

6.4) Assay for holoTC Using mAb 3C4 as Detecting Antibody

The binding events were followed in real time using surface plasmon resonance and performed on a Biacore instrument (Biacore™, Sweden). An anti-human TC monoclonal antibody directed against epitope 2 of TC was immobilized on a dextran coated CM5 chip, as described in Example 2.1, above. The chip with immobilized antibody was introduced into the instrument, after which was injected 15 μL of 18 ng/μL holoTC and apoTC. The proportion of holoTC to apoTC varied from 0:100 to 100:0, but the total amount was always the same, 18 ng/μL. Then 5 μL of 50 ng/μL mAb 3C4 was injected and the amount of antibody bound was recorded in the sensorgram. FIG. 5 a depicts a typical standard curve. FIG. 5 b depicts a curve generated in the same way wherein the cature ligand for epitope 2 was mAb TC7.

6.5) Conjugation of Monoclonal Antibody 3-11 with Horse-radish Peroxidase

Mab 3-11 was conjugated to horse-radish peroxidase (HRP) using the EZ-LinkT™ Maleimide Activated HRP kit (Pierce, USA) and a protocol supplied by the manufacturer. In short, mAb 3-11 in PBS is modified with a 25-fold molar excess of SATA (N-succinimidyl S-acetylthioacetate) in DMF (dimethylformamide) and after 30 min deprotected with a 90-fold molar excess of hydroxylamine for 2 h at ambient temperature. The thiolated antibody is desalted and then allowed to react with a 8-fold excess of EZ-Link™ Maleimide Activated HRP at ambient temperature for 1 h. The conjugate is dialyzed three times against a 100-fold excess volume of PBS.

6.6) Conjugation of Antibody 3-11 with Alkaline Phosphatase

mAb 3-11 was biotinylated using EZ-Link™ Sulfo-NHS-LC-Biotinylation kit (Pierce, USA) and a protocol supplied by the manufacturer. In short, 10 nmol of mAb 3-11 in PBS is mixed with 20-fold molar excess of Sulfo-NHS-LC-Biotin in deionized water. Kept on ice for 2 h and then purified protein on a gel filtration column equilibrated with PBS. Finally biotinylated antibody is allowed to bind streptavidin-conjugated alkaline phosphatase (Jackson ImmunoResearch Laboratories, Inc, USA).

6.7) Non-Isotopic Sandwich Assay for holoTC Using mAb 3C4 as Capture Antibody

Maxisorb plates (NUNC-Immuno™, Denmark) were coated with 10 μg/mL mAb 3C4 in PBS over night at 4° C. and then blocked with 10 mg/mL BSA in PBS for 2 h at ambient temperature. To each well was added 50 μL of serum and 50 μL of PBS, and allowed to incubate for 30 min at ambient temperature. After washing three times with 200 μL of PBA+0.05% Tween (PBA+), 100 μL of HRP-conjugated mAb 3-11 (see 6.5) was added and the mixture left to incubate for 30 min at ambient temperature. Each well was washed three times with 200 μL PBA+ and 200 μL of the HRP-substrate, TMB (3,3′,5,5′-tetramethylbenzidine; Kirkegaard & Perry Laboratories, USA) was added and incubated for 10 min. The reaction was quenched with 100 μL of 0.12M HCl and the color development measured at 450 nm. A typical standard curve is depicted in FIG. 4B.

6.8) Non-isotopic Sandwich Assay for holoTC Using scFv 3C4 as Capture Antibody

Maxisorb plates (NUNC-Immuno™, Denmark) were coated with 10 μg/mL anti-his-tag mAb (abcam, UK) in PBS over night at 4° C. and then blocked with 10 mg/mL BSA in PBS for 2 h at ambient temperature. To each well was added 50 μL of holoTC and 50 μL of PBS, and allowed to incubate for 30 min at ambient temperature. After washing three times with 200 μL of PBA+0.05% Tween (PBA+), 100 μL of HRP-conjugated mAb 3-11 (see 6.5) was added and the mixture left to incubate for 30 min at ambient temperature. Each well was washed three times with 200 μL PBA+ and 100 μL of the HRP-substrate, TMB (3,3′,5,5′-tetramethylbenzidine; Kirkegaard & Perry Laboratories, USA) was added and incubated for 10 min. The reaction was quenched with 100 μL of 0.12M HCl and the color development measured at 450 nm. Typical standard curves using wt and two engineered mutants are depicted in FIG. 4C.

6.9) Non-isotopic Bead Assay for holoTC Using mAb 3C4 as Capture Antibody

50 μL of serum and 50 μL of PBS were mixed with 10 μL of mAb 3C4 coated magnetic beads. After incubation at ambient temperature for 20 min, beads were separated by using a magnetic rack, washed six times with 200 μL pf PBA+, and resuspended in 100 μL of AP-conjugated mAb 3-11. After 20 min, beads were separated on the magnetic rack, washed six times with PBA+, added Lumiphos®Plus substrate (Aureon Biosystems GmbH, Austria), and read in a luminometer. A typical standard curve is seen in FIG. 4D.

EXAMPLE 7 Comparison Assay with Commercial Assay

Fifteen serum samples with holoTC values ranging from 14 pM to 139 pM as determined by a commercially available assay for holoTC, HoloTC RIA®, were quantified by the assay for holoTC described in Example 6.3. A comparison of the values obtained by the two methods showed a good correlation (r=0.96) (FIG. 6 a).

Twenty four serum samples with holoTC values ranging from 24 pmol/L to 148 pmol/L as determined by a commercially available assay for holoTC, HoloTC RIA®, were quantified by the assay for holoTC described in Example 6.7. A comparison of the values obtained by the two methods showed a good correlation (r=0.98) (FIG. 6B).

EXAMPLE 8 Dual Assay for holoTC and apoTC

The binding events were followed in real time using surface plasmon resonance and performed on a Biacore instrument (Biacore™, Sweden). The capture antibody—a high affinity anti-human TC monoclonal antibody directed against epitope 2 of TC—was immobilized on a dextran coated CM5 chip, as described in Example 2.1, above. The chip with immobilized antibody was introduced into the instrument, after which was injected 15 μL of a mixture of holoTC and apoTC. The relative amounts of holoTC and apoTC varied but the total concentration of TC was constant, 18 ng/μL. The amount of holoTC bound was determined by injection of 60 μL of 400 ng/μL of the holoTC specific antibody, mAb 3C4. The amount of mAb 3C4 bound was recorded in the sensorgram. The chip was subjected to a wash step and then the amount of apoTC bound was determined by injection of 5 μL of 25 ng/μL of mAb TC2. mAb TC2 is specific for TC but overlaps completely with mAb 3C4 on holoTC, and thus when injected subsequent to mAb 3C4 detects only the apoTC fraction. FIGS. 7 a and 7 b depict the relation between apoTC and holoTC captured by the first antibody and the amount of mAbs 3C4 and TC2 bound. Because mAb 3C4 is a low affinity antibody complete blockage of holoTC is difficult to obtain, but because holoTC only makes up 6-25% of the total TC, >90% blockage is sufficient. In FIG. 7 b, the first antibody is TC7.

EXAMPLE 9 Dual Assay for holoTC and apoTC

An anti-human TC specific monoclonal antibody, non-overlapping with epitopes 4 or 5, e.g. directed against epitope 2, is immobilized on magnetic beads as described in Example 2.1, above. An aliquot of serum or plasma (100-500 μL) is mixed with 1/10^(th) volume of the immobilized antibody and optionally with PBS (>100 μL) and allowed to incubate for 30 min at ambient temperature. The beads are sedimented using a magnet, washed twice with PBS and resuspended in PBS containing 1 mg/mL of BSA. An excess of mAb 3C4 conjugated to a signal giving moiety is added and incubated for 30 min, and the beads are then sedimented and washed as above, and resuspended in PBS containing 1 mg/mL of BSA. An excess of mAb TC2 conjugated to a different signal giving moiety is added and the mixture incubated for 30 min at ambient temperature. Beads are sedimented and washed as above. Finally, the bound mAb 3C4 and TC2 are measured using their respective signal giving moiety, and the holoTC and apoTC concentrations are determined by interpolation on a standard curve.

EXAMPLE 10 Dual Assay for holoTC and Total TC: TC Saturation

The binding events were followed in real time using surface plasmon resonance and performed on a Biacore instrument (Biacore™, Sweden). The capture antibody—a high affinity anti-human TC monoclonal antibody directed against epitope 2 of TC—was immobilized on a dextran coated CM5 chip, as described in Example 2.1, above. The chip with immobilized antibody was introduced into the instrument, after which was injected 15 μL of a mixture of holoTC and apoTC. The relative amounts of holoTC and apoTC varied but the total concentration of TC was constant, 18 ng/μL. The amount of holoTC bound was determined by injection of 60 μL of 400 ng/μL of the holoTC specific antibody, mAb 3C4. The amount of mAb 3C4 bound was recorded in the sensorgram. The chip was subjected to a wash step and then the total amount of TC bound was determined by injection of 15 μL of 100 ng/μL of mAb 3C12. mAb 3C12 is specific for TC and binds to epitope 6 which is non-overlapping with epitopes 2 and 4 (FIG. 3). By allowing mAbs 3C4 and 3C12 to bind the immobilized holoTC/apoTC, simultaneously or consecutively, the contents of both holoTC and total TC may thus be determined and expressed as absolute values or as the saturation level. FIG. 8 shows a typical standard curve for TC saturation. FIG. 9 depicts the binding of antibodies 3C4 and 3C12 to holoTC and total TC in the sample, respectively.

Table 6. Sequences of the single-chain Fv antibody fragments of monoclonal antibodies TC2 and 3C4.

VH sequences in capital letters followed by the linker sequence in lower case letters and finally VL sequences in capital letters:

EXAMPLE 11 Single Chain Antibody Fragments Corresponding to mAbs TC2 and 3C4

Single chain antibodies corresponding to TC2 and 3C4 were generated and sequenced. The sequences are shown in Table 6 wherein for each scFv the heavy chain variable region (VH) is shown in capitals, followed by the linker sequence in lower case, followed by the light chain variable region (VL) sequence. The scFVs having the sequences shown in Table 6 were immobilised on SPR chips and the binding keinetics compared with those of the corresponding whole IgG antibodies using the method described in Example 2. The results are shown in Table 7 which demonstrates that the specificity of the scFvs was equivalent to that of the corresponding whole antibodies.

TABLE 6 Sequences of scFvs TC2_ScFv (Seq. ID No. 16) CAGGTGCAGCTGAAACAGTCAGGACCTGGCCTACTGCAGCCCTCCCAGAG CCTGTCCATCACCTGCACAGTCTCTGGTTTCTCATTAACTTACTATGGTG TACACTGGGTTCGCCAGTCTCCAGTAAAGGGTCTGGAGTGGCTGGGAGTG ATATGGAGTGGTGGAGACACAGACTATGATACAACTTTCATATCCAGACT GAGCATCAGCAAGGACAATTCCAAGGGCCAAGTTTTCTTTAAGATGACCA GTCTGCAAACTGATGACACAGCCATATATTACTGTGCCAGAGGAAGGACC TATGGTATCCACTTTGACTACTGGGGCCAAGGCACCACTCTCACAGTCTC CTCAggtggaggcggttcaggcggaggtggatccggcggtggcggatcgG ACATTGTGATGTCACAGTCTCCATCCTCCCTGGCTGTGTCAGTAGGAGAG AAGGTCACTATGAGCTGCAAATCCAGTCAGAGTCTGTTCAACAGTAGAAC CCGAAAGAACTACTTGGCTTGGTACCAGCAGAAACCAGGGCAGTCTCCTA AAGTTCTGATCTACTGGGCATCCACTAGGGAATCTGGGGTCCCTGATCGC TTCACAGGCAGTGGATCTGGGACAGATTTCACTCTCACCATCAGCAGTGT GCAGGCTGAAGACCTGGCAATTTATTACTGCAAGCAATTTTATGATCTGT GGACGTTCGGTGGAGGCACCAAGCTGGAAATCAAACGG 3C4_ScFv (Seq. ID No. 17) GAGGTGCAGCTTCAGGAGTCGGGACCTGGCCTGGTGAAACCTTCTCAGTC TCTGTCCCTCATCTGCACTGTCACTGGCTACTCAATCACCAGTGATTATG CCTGGAACTGGATCCGGCAGTTTCCAGGAAACAAACTGGAGTGGATGGGC TACATAAGCTACAGTGGTTCCACTAGCTACAACCCATCTCTCAAAAGTCG AATCTCTATCACTCGAGACACATCCAAGAACCAGTTCTTCCTGCAGTTGA ATTCTGTGACTACTGAGGACACAGCCACATATTACTGTGCAAGACCCTAT TACTACGGTATTAGGGGGTTTGCTTACTGGGGCCAAGGGACTCTGGTCAC TGTCTCTGCAggtggaggcggttcaggcggaggtggatccggcggtggcg gatcgGACATCCAGATGACTCAGTCTCCAGCCTCCCTATCTGCATCTGTG GGAGAAACTGTCACCATCACATGTCGAGCAAGTGAAAATATTTACAGTTA TTTAGCATGGTATCAGCAGATACAGGGAAAATCTCCTCAGCTCCTGGTCT ATAATTCAAAAACCTTAGCAGAAGGTGTGCCATCAAGGTTCAGTGGCAGT GGATCAGGCACACAGTTTTCTCTGAAGATCAACAGCCTGCAGCCTGAAGA TTTTGGGAGTTATTACTGTCAACATCATTATGTTACTCCGTACACGTTCG GAGGGGGGACCAAGCTGGAAATAAAACGG

TABLE 7 Amino acid sequences of scFvs TC2_ScFv (Seq. ID No. 18) QVQLKQSGPG LLQPSQSLSI TCTVSGFSLT YYGVHWVRQS PVKGLEWLGV IWSGGDTDYD TTFISRLSIS KDNSKGQVFF KMTSLQTDDT AIYYCARGRT YGIHFDYWGQ GTTLTVSSGG GGSGGGGSGG GGSDIVMSQS PSSLAVSVGE KVTMSCKSSQ SLFNSRTRKN YLAWYQQKPG QSPKVLIYWA STRESGVPDR FTGSGSGTDF TLTISSVQAE DLAIYYCKQF YDLWTFGGGT KLEIKR 3C4_ScFv (Seq. ID No. 19) EVQLQESGPG LVKPSQSLSL ICTVTGYSIT SDYAWNWIRQ FPGNKLEWMG YISYSGSTSY NPSLKSRISI TRDTSKNQFF LQLNSVTTED TATYYCARPY YYGIRGFAYW GQGTLVTVSA GGGGSGGGGS GGGGSDIQMT QSPASLSASV GETVTITCRA SENIYSYLAW YQQIQGKSPQ LLVYNSKTLA EGVPSRFSGS GSGTQFSLKI NSLQPEDFGS YYCQHHYVTP YTFGGGTKLE IKR

TABLE 8 Comparison of the binding kinetics for anti-human TC IgG and scFv antibodies as measured by SPR (BIAcore). k_(on), 10⁴ Anti- (L mol⁻¹ k_(off), 10⁻⁴ Ka, 10⁷ body Format Antigen s⁻¹) (s⁻¹) (L mol⁻¹) 3C4 IgG1 HoloTC 3 24 1.3 3C4 IgG1 ApoTC 0 0 0 3C4 scFv HoloTC 0.6 24 0.3 3C4 scFv ApoTC 0 0 0 TC2 IgG1 HoloTC 10 4 25 TC2 IgG1 ApoTC 10 15 7 TC2 scFv HoloTC 0.4 15 0.3 TC2 scFv ApoTC N/D 15 N/D kon = association rate constant (M⁻¹s⁻¹) koff = disociation rate constant (s⁻¹) Ka = kon/koff (M⁻¹)

EXAMPLE 12 Preparation of Single Chain Antibody Fragments from mRNA Using Commercial Methods

12.1). Preparation of mRNA

Pure mRNA is prepared from hybridoma cells using the QuickPrep® mRNA Purification Kit (Amersham Biosciences) and the protocol supplied therewith.

12.2). Conversion to cDNA

The mRNA is used as a template to prepare cDNA. Random hexamer primers are used to prime cDNA synthesis and generate a cDNA:mRNA heterduplex using the First-Strand cDNA Synthesis kit (Amersham Biosciences) and supplied protocol.

12.3). PCR of V_(H) and V_(L) Genes.

The cDNA:mRNA heterduplex is heat denatured and the cDNA strand used as template for PCR, in the presence of specific primers designed for the amplification of V_(H) and V_(L) domains from the Light and Heavy Primer Mix (Amersham Biosciences). Alternatively, several such primers are given in the literature (e.g. from McCafferty, supra) and may be prepared by standard synthetic methods.

12.4). Purification of Amplified V_(H) and V_(L) Genes

The amplified V_(H) and V_(L) chain PCR fragments are purified separately by electrophoresis on a 2% low melting point agarose gel with ethidium bromide staining. The V_(H) and V_(L) bands are carefully excised and the PCR product recovered with S.N.A.P.™ Gel Purification Kit (Invitrogen, cat.no. K1999-25) or a similar commercial product.

12.5). Assembly of V_(H) and V_(L) Genes into scFv Genes

The V_(H) and V_(L) chain domains are linked together using the linker fragment (GGGS)₃ to give a complete scFv sequence.

The linker is flexible enough to allow the V_(H) and V_(L) domains to maintain their antigen binding conformation and connects the V_(H) and V_(L) domains. Other linkers are well know and comprise around 15 amino acids.

12.6). PCR Amplification, Digestion, and Ligation to Phagemid.

The scFv antibody is amplified using primers which incorporate sites for restriction enzymes (Sfi I and Not I (Promega)). The amplified DNA is purified as in 12.4 above, digested with these enzymes and finally subcloned into the phagemid pCANTAB-5E (Amersham Biosciences).

12.7 Transformation and Expression of Soluble Antibodies.

The vector containing the scFv gene is introduced into E. Coli cells by electroporation and the cells grown under conditions that will allow only vector infected cells to grow. Preferably a strain of E. Coli is chosen that transports the synthesized protein into the periplasmic space (e.g. HB2151).

To simplify purification of the synthesized scFv antibody, the scFv gene in 12.6 may be subcloned into an expression vector inserting a “tag” at the C-terminus of the antibody (e.g. pCANTAB6; his-tag). The “tag” is recognized by a monoclonal antibody and may be used for affinity-chromatography purification.

12.8 Transformation and Expression of scFv Antibodies on the Surface of Bacteriophage.

The vector pCANTAB5E containing the scFv gene is introduced into a suppressor strain of E. Coli (e.g. TG1), which allows the scFv antibody to be displayed on the surface of the phage. Phage particles displaying scFv antibodies are prepared essentially as described in 4.2

EXAMPLE 13 Affinity Maturation of scFv 3C4 Using Phage Display

To construct a scFv library displayed on the surface of bacteriophage essentially the steps of Example 12 is followed but a PCR mutagenesis method is introduced at step 12.6. Several such methods are described but a non-localized mutagenesis strategy such as error-prone PCR (e.g. Genemorph® Random mutagenesis kit, Stratagene, USA) or chain-shuffling (e.g. Fragment Induced Diversity, FIND™, Alligabor Bioscience AB, Sweden) to randomly introduce mutations throughout the V-genes is generally recommended. In the latter case, at least two different scFv antibody clones are required between which to shuffle the chains (Table 6). Biopanning of the mutant libraries is then performed to select clones of higher affinity.

13.1). Error-prone PCR Amplification.

The scFv antibody DNA is PCR amplified using sequencing primers for antibody V genes and Taq polymerase, in the presence of 0.5-2.0 mM MnCl2, which reduces the fidelity of the Taq polymerase. The amplified DNA is purified, digested, and subcloned as described in Example 12.

13.2) Chain-Shuffling (FIND™, Alligator Bioscience AB)

At least two different scFv antibody DNA are fragmented with an exonuclease (e.g. BAL31; Fermentas Life Sciences, Lithuania) to generate populations of single stranded fragments. The ssDNA fragments are purified by phenol extraction/ethanol precipitation followed by electrophoresis as described in 12.4. The ssDNA fragments are reassembled and amplified by PCR using primer sequences that anneal to the 3′ and 5′ ends of the fragments. The annealed scFv are purified, and subcloned as described in Example 12.

13.3) Biopanning of Mutant Libraries.

The generated libraries were of size 10⁵-10⁶ individual clones. Holo-TC was biotinylated as described in 6.6 and bound to streptavidin coated beads (Dynabeads®, Dynal Biotech, Norway). The biopanning procedure was performed essentially as described in 4.2. To assure that holoTC specificity was not compromised, the biopanning was carried out in the presence of at least a 100-fold excess of apoTC. Alternatively, libraries were pretreated with excess apoTC immobilized on magnetic beads.

13.4) Screening ELISA

Individual phage antibody clones were screened by ELISA essentially as described in 4.3, using holoTC coated microtiter plates. The plates were prepared by binding biotinylated holoTC onto streptavidin coated microtiter wells (NUNC™, Denmark). Selected phage antibodies were transformed and expressed as soluble scFv antibodies, as described in 12.7.

13.5) Evaluation of Selected scFv Antibodies

Selected scFv antibodies were evaluated by surface plasmon resonance essentially as described in Example 2. Purified antibody preparations were injected over a chip with immobilized holoTC. The holoTC chip was prepared by binding holoTC to a chip prepared as described in 2.1 or by binding biotinylated holoTC on a streptavidin coated SA chip (Biacore, Sweden). The results obtained are shown in Tables 9 and 10.

TABLE 9 Affinity measurements of mutated scFv 3C4 from first round of library constructions. Clone Sequence* koff kon KD 3.10E5 P14S, A34T, A97V, 2.9E−04 1.2E+04 2.4E−08 2.7G5 A34T, T87S, S200N, 2.3E−04 9.1E+03 2.6E−08 3.7D9 A34T, F41L 3.1E−04 9.5E+03 3.2E−08 3.3D7 A34T, S198N 4.8E−04 8.7E+03 5.5E−08 2.10H3 A34V, L46M 5.0E−04 8E+03 6.2E−08 2.9A11 A34T 3.6E−04 5.3E+03 6.9E−08 3.10D1* A34T, S53N 6.4E−04 5.1E+03 7.1E−08 3.2H8 A34T, T232R 4.8E−04 6.0E+03 8.0E−08 3.7C10 A34V 5.6E−04 7.0E+03 8.0E−08 3.9G2 Q16L, T30A, A34T, 5.9E−04 3.8E+03 1.5E−07 3.9D1 G8V, A34T, S147Y 6.6E−04 1.8E+03 3.7E−07 3.10H8 A34T, E216G 9.0E−04 2.2E+03 4.0E−07 2.4F10 wt 3.10E−03  6.4E+03 4.9E−07 *Shows substitutions in the sequence given in Table 7. wt, wild type, i.e. nonmutated scFv 3C4. kon = association rate constant (M⁻¹s⁻¹) koff = disociation rate constant (s⁻¹) KD = koff/kon (M) Bold - substitution in complimentarity determining region (CDR).

TABLE 10 Affinity measurements of mutated scFv 3C4 from second round of library constructions. Clone name Sequence* koff F1.3E4 P14S, A34T 3.30E−04 F1.3H8 P14S, A34T, A97V 4.10E−04 F1.3E5 P14S, A34T, S53N,

4.40E−04 F1.8D9 P14S, A34T, T87S, R159L 4.50E−04 F1.7E7 P14S, A34T, A97V,

6.04E−04 F1.8C12 P14S, A34T, A97V,

,

, 6.10E−04 3.10E5 P14S, A34T, A97V, R159L 6.50E−04 F1.8C10 A34T, T87S, A97V,

,

, 7.20E−04 F1.9C4 A34T,

, A97V, S200N, G201R 7.70E−04 *Shows substitutions in the sequence given in Table 7. Bold italic - new amino acid changes compared to Table 9

The koff values reported are generally higher than those of Table 9 because the amount of bound antigen was lower in this experiment, 500RU as compared to 3500RU, and thus less rebinding occurred.

EXAMPLE 14 Reconfiguration of scFv Antibodies Back into Full Length Antibody Format

The scFv antibody fragments are reconfigured back to full length antibody format by joining the scFv from cDNA clones to mouse or human genomic constant regions using standard recombinant DNA techniques (e.g. McCafferty J. Hoogenboom H R, and Chiswell D J (ed.) (1996) Antibody Engineering—A practical approach, IRL Press, Oxford, UK). The chimaeric heavy and light chain immunoglobulin genes are placed under the control of a strong viral promotor (e.g. hCMV-MIE), and cotransfected into cell line COS-1 (ATCC#CRL1650) or myeloma cell line NS0 (ATCC#85110503), for transient and stable expression of antibody, respectively. To mimimize risk of interfering autoantibodies against mammalian IgG Fc (e.g. rheumatoid factor), reconfiguration may be performed into the IgG3 format, which is less susceptible to such autoantibodies.

14.1) Transfection of COS-1 Cells.

The COS-1 cells are plated out on a Petri dish the day before transfection. Plasmid DNA, containing the gene to be expressed, are transfected into the cells using e.g. Fugene 6 (Roche) and antibody harvested from the medium after 3 days.

14.2) Transfection of NS0 Cells.

Plasmid DNA are transfected into about 10E7 NS0 cells on ice by electroporation. Cells are then grown in selective medium allowing only transfected cells to survive. Antibody is harvested from cell medium three weeks post-transfection.

EXAMPLE 15 Epitope Mapping of Aptamer b974-3t1

The epitope specificity of 18,000 Da aptamer b974-3t1 was determined.

15.1 Binding of Aptamer to holoTC Immobilised on Various anti-humanTC mAbs

An array of 10 different anti-human TC antibodies were immobilised onto a dextran coated chip which had been pre-coated with rabbit anti-mouse IgGs. The procedure was as described above for Example 2.2. HoloTC (15 μl, 0.4 μM) was injected and allowed to bind to the mAb, followed by aptamer b974-3t1 15 μl, 1 μM).

15.2 Binding of holoTC by Immobilised aptamer in the Presence and Absence of Various Anti-humanTC mAbs

Aptamer b974-3t1 was immobilised on strepatvidin coated magnetic particles (0.8 μm) in a method analagous to Example 3.1 above, substituting streptavidin particles for the anti-mouse IgG coated particles of that Example. The particles were then allowed to capture native holoTC as described in Example 3.2 above, in the presence of 9 different TC-specific antibodies. All antibodies were present at 10 μg/ml except for 5H2 and 3C4 which were tested at 100 μg/ml.

TABLE 11 Binding of aptamer to holoTC immobilised on various mAbs and binding of holoTC to immobilised aptamer in the presence of various mAbs Binding of: holoTC to aptamer to aptamer in Overlap holoTC captured presence of + small by mAb mAb ++ medium Epitope mAb (mRU/RU) (% of w/o mAb) +++ full 1 3-9 135 7 + 2A 2-2 0 n.d. +++ 2A  3-11 0 3 +++ 2A TC7 0 3 +++ 2B 5H2 0 41 ++ 2B 4-7 88 54 ++ 3 TC4 104 100 + 4 3C4 39 60 ++ 5 TC2 97 69 ++ 6 3C12 0 3 +++

As seen in Table 11, aptamer b974-3t1 overlaped completely or almost completely with epitope 6 antibodies and with some epitope 2 antibodies (2A). Ambiguous results were obtained with mAb 3-9 and to some extent with 5H2; the aptamer and the mAb both bound simmultaneously to holoTC in one setting but not in the other, however, it is not unusual for the mode of presentation to affect binding efficiency. Since simmultaneous binding was seen in at least one experiment, complete overlap is excluded.

In line with the strong overlap of the aptamer with epitope 6, the overlap with heparin is also very strong (see FIG. 3 for epitope map and FIG. 10 for inhibition data).

EXAMPLE 16 Capture of holoTC by holoTC Specific Antibody 3C4 and Detection by Aptamer b974-3t1

The binding events were followed in real titne using surface plasmon resonance and performed on a Biacore instnnnbnt (Biacore™, Sweden). Monoclonal antibody 3C4 was immobilized on a dextran coated CM5 chip, as described in Example 2.1 above. The chip with immobilized antibody was introduced into the instrument, after which was injected 15 μL of 0.4 M holoTC or apoTC and subsequently 15 μL of 1 μM aptamer b974-3t1. The aptamer bound to a level of about 10 RU to the captured holoTC; 39 mRU of aptamer bound per RU of holoTC captured (FIG. 11, upper curve). As no apoTC was captured by the holoTC specific mAb 3C4, no aptamer bound either in this second case (FIG. 11, lower curve).

EXAMPLE 17

Capture of apoTC and holoTC by Immobilized TC-specific Aptamer b974-3t1 and Detection of Bound holoTC Using mAb 3C4 and total TC (apoTC and holoTC) by Epitope 2 Antibody, mAb 4-7.

17.1 Immobilization of Aptamer on Streptavidin Coated SA Chip

Biotinylated aptamer b974-3t1 was immobilized on a streptavidin coated SA chip (Biacore, Sweden). The aptamer was diluted to about 18 μg/ml in 0.01 M HEPES buffer, pH 7.4, 0.15 M NaCl, 0.005% (v/v) surfactant P20 supplemented with 2 mM CaCl₂ and 2 mM MgCl₂ (HBS-P+) and injected over the chip at 5 μL/min for 7 min. The binding of aptamer was followed in real time and the amount of mass bound was recorded in RU (response units) in the sensorgram. The aptamer was immobilized on the chip to about 1500 RU.

17.2 Binding of apoTC and holoTC to Immobilized Aptamer

ApoTC and holoTC were diluted in HBS-P+ to about 18 μg/mL and injected over the chip with the immobilized aptamer at 5 μL/min for 7 min. The amount of mass bound was recorded in the sensorgram.

17.3 Detection of Bound apoTC and holoTC by Monoclonal Antibodies Speciftc for TC and holoTC

Monoclonal antibody mAb 3C4, specific for holoTC, diluted to 50 μg/mL in HBS-P+ was injected over the chip with captured apoTC or holoTC at 5 μL/min for 1 min. Thereafter a monoclonal antibody with specificity for TC but without holoTC specificity and with an epitope non-overlapping with mAb 3C4 (epitope 2 antibody; mAb 4-7) was injected at 5 μL/min for 1 min. The mass bound of each mAb was recorded in the sensorgram.

FIG. 12 depicts a typical sensorgram showing capture of apoTC and holoTC by the immobilized aptamer, followed by binding of mabs 3C4 and 4-7 to the captured TC. The arrows identify injections of TC (inj.), mAb 3C4 (3C4) and mAb 4-7 (4-7), and wash (w). Whereas mAb 3C4 bound only to captured holoTC, mAb 4-7 bound equally well to apoTC and holoTC (Table 12). As shown in FIG. 12, aptamer b974-3t1 exhibited a slight specificity for holoTC over apoTC (i.e. the amount of TC bound to the chip was greater when it was in the holo form). The preference was estimated to be about 3-fold.

TABLE 12 Binding of mAbs 3C4 and 4-7 to apoTC and holoTC captured by aptamer b974-3t1 Bound mAb 3C4* Bound mAb 4-7* TC (%) (%) ApoTC 0 104 HoloTC 39 106 *Results expressed relative to amount of TC captured.

EXAMPLE 18 Ab Initio Prediction of Human Transcobalamin 3D Structure

The simulation was performed using the HMMSTR/Rosetta prediction server. The HMMSTR/Rosetta server predicts the structure of proteins from the sequence: secondary structure in the form of 3-states (H,E,L), local structure in the form of backbone torsion angles (phi,psi), supersecondary structure in the form of context symbols (for strands and beta turns), and teriary structure in the form of coordinates. (C. Bystoff, V. Thorsson, D. Baker) HMMSTR is a hidden Markov model based on the I-sites Library of sequence-structure motifs. I-sites predicts local structure motifs in the query, and these are then used by Rosetta to generate the 3D structure. Rosetta is a Monte Carlo Fragment Insertion protein folding program developed by Kim Simons, David Baker, Ingo Rudzinski and Charles Kooperberg (Simons et al, 1997). The amino acid sequence of human transcobalamin was taken from Swissprot ID no. P20062.

FIG. 13 shows the predicted 3D structure of apotranscobalamin with the deletion mutation (see Example 2.4) in ribbon format. Upper FIG. 13 shows the front of TC with the mAb 3C4 epitope (from Example 19) depicted as rose spheres. Lower FIG. 13 shows the back of TC with the tentative heparin binding site depicted as spheres.

The predicted spatial proximity of the 27 amino acid deletion and the putative heparin binding site is corroborated by our experimental finding (Examples 2 and 13) that antibodies to epitope 2, which overlap with the deletion mutation, are inhibited by heparin and aptamer b974-3t1, which both bind to the heparin binding site. Furthermore, because antibodies to epitope 6 are inhibited by heparin and aptamer b974-3t1 and to some extent by epitope 1 and 2 antibodies, the 3D structure indicates that epitope 6 straddles the heparin binding site.

FIG. 14 shows a cartoon of the holoTC structure as a three sided pyramid and depicting the localization of different antibody epitopes based on experimental data.

EXAMPLE 19 Ab Initio Prediction of the Epitope of mAb 3C4 on holoTC

Simulations of the docking of cobalamin with apoTC and the docking of mAb 3C4 with holoTC were performed by Cambridge Proteomics Ltd using their proprietary simulation technology. The amino acid sequence of apotranscobalamin was taken from Swissprot ID no. P20062. The chain was initially shaped randomly. The disulfides known to be formed between cysteines 21 and 267, 83 and 96, 116 and 309, and 165 and 205 (SN Fedosov et al, J Biol Chem 1999; 274:26015-20) were programmed to be created when the sulfurs in the respective cysteine residues approached a distance of 2.038±0.05 Å. The 3D cobalamin structure was taken from the PDB entry 1BMT (methionine synthase B12 binding regions) and relaxed in water before reacting with TC. As reported in the literature, cobalamin binding caused significant structural changes in TC (E Hippe, Biochem Biophys Acta 1970; 208:337-9).

As we had only determined the amino acid sequence of the CDR region of mAb 3C4 (Table 7) the initial structure was based on the mAb 3C4 CDR sequence inserted into the human IgG1 model (EA Padlan, Mol Immunol 1994;31:169-217). The variable regions were initially shaped randomly.

When simulating the interaction between mAb 3C4 and holoTC, the initial orientation was chosen randomly, with the binding region of the antibody pointing between the C165-C205 loop and the C-terminal end (320-427) of holoTC. The initial distance between antibody and holoTC was over 10 Å and the ionic strength of the solution was set at 50.

All simulations were run on a Linux work station running on Intel Xeon processors.

The epitope was defined as those amino acids in holoTC, which in the predicted complex are localized <5 Å from amino acids in the antibody. 36 amino acids fulfilled these requirements, and can be organized into three discrete regions spanning amino acids 39-77 plus 265-269, 161-243, and 271-297 (Table 13A). Including adjacent amino acids, the number of amino acid residues defining the epitope is 68 (Table 13B). The epitope is localized around a tunnel in the protein (FIG. 13). On the other side of the tunnel cobalamin is bound.

In the antibody, the amino acids corresponding to the epitope and the extended epitope were 32 and 39, respectively, constituting the paratope and the extended paratope. The amino acids are organized in two regions, 14 and 16 residues in the VL chain and 18 and 23 residues in the VH chain for the paratope and the extended paratope, respectively (Tables 14A and B).

The interaction between the paratope (antibody) and the epitope (holoTC) and involved residues is depicted in FIG. 15A. The corresponding interaction between the extended paratope and extended epitope is depicted in FIG. 15B.

TABLE 13A Epitope residues Amino acid region Amino acids  39-77, 265-269 L39, M42, N51, P52, I54, Q64, A65, E69, L73, L76, K77, T265, A266, K269 161-243 I161, H172, V176, L180, T195, A196, R208, H239, N242, V243 271-296 R271, V272, A273, L274, A276, Q279, Q284, M288, L293, P294, V295, L296

TABLE 13B Extended epitope Amino acid region Amino acids 39–77, 265–269 L39, M42, L50, N51, P52, S53, I54, Q64, A65, E69, D70, L71, Y72, L73, H74, S75, L76, K77, T265, A266, K269 161–243 I161, H172, D173, S174, V175, V176, D177, K178, L179, L180, Y181, A182, V183, E184, T195, A196, R208, H239, N242, V243 271–296 R271, V272, A273, L274, L275, A276, S277, L278, Q279, D280, G281, A282, F283, Q284, N285, A286, L287, M288, I289, S290, Q291, L292, L293, P294, V295, L296, N297

TABLE 14A Paratope residues. Chain Amino acids VL E1, Q3, Q5, T25, G26, Y27, S28, Y54, S55, Y100, Y101, Y102, R105, Q112 VH S31, Y32, K42, S43, Q45, L46, Y49, N50, T53, L54, E56, G57, V58, P59, S60, R61, E81

TABLE 14B Extended paratope Chain Amino acids VL E1, V2, Q3, Q5, T25, G26, Y27, S28, S53, Y54, S55, Y100, Y101, Y102, R105, Q112 VH S31, Y32, L33, A34, W35, K36, K42, S43, P44, Q45, L46, Y49, N50, T53, L54, E56, G57, V58, P59, S60, R61, E81 

1. A specific binding partner for holoTC having a specificity for holoTC over apoTC of at least 40-fold wherein said specific binding partner is an antibody, a single chain antibody, an antibody fragment or an antibody construct.
 2. The specific binding partner for holoTC of claim 1 wherein the binding of said specific binding partner to holoTC is blocked by binding of a specific binding partner having affinity for site present on both holoTC and apoTC which overlaps with the binding site on holoTC of said specific binding partner for holoTC.
 3. The specific binding partner of claim 1 wherein the specific binding partner is an antibody, a single chain antibody, and antibody fragment, an antibody construct.
 4. The specific binding partner of claim 1 wherein the specific binding partner is antibody 3C4 as deposited at the European Collection of Cell Cultures under accession number
 02110741. 5. The specific binding partner of claim 1 wherein the specific binding partner is a single chain antibody with amino acid sequence of SEQ ID NO:19, or an affinity matured single chain antibody thereof or a recombinant antibody thereof.
 6. The specific binding partner of claim 1, having affinity for a conformational epitope of holoTC which is not present in apoTC.
 7. The specific binding partner of claim 1, wherein said specific binding partner has an affinity for a peptide sequence of SEQ ID NO:
 3. 8. The specific binding partner of claim 1, wherein said specific binding partner has an affinity for a peptide sequence of SEQ ID NO:
 8. 9. The specific binding partner of claim 1, wherein said specific binding partner has an affinity for the peptide sequences of SEQ ID NO:3 and SEQ ID NO:8.
 10. The specific binding partner of claim 1, wherein said specific binding partner has an affinity for a peptide sequence selected from the group consisting of SEQ ID NO: 3, SEQ ID NO: 4, SEQ ID NO: 5, SEQ ID NO: 6, SEQ ID NO: 8, and SEQ ID NO:
 9. 11. The specific binding partner of claim 6 also having affinity for at least one cyclic peptide comprising the motif SX1 X2YX3 WD X4 X5 X6 where X1=F, G, L X2=F, L, R X3=L, P, Q X4=M, Q, Y X5=D, F X6=M, R or the motif SFFYSLCYCW (SEQ ID NO:9), relative to apoTC of at least 40-fold.
 12. The specific binding partner of claim 6 which binds to at least one point in at least one of the regions I, II or III of human TC of SEQ ID No. 1: I) Leu 39to Lys 77 and Thr265 to Lys 269 II) Ile 161 to Val 243 III) Arg 271 to Asp
 297. 13. A kit for assaying for holoTC in a sample, said kit comprising a specific binding partner for holoTC of claim
 1. 14. The kit of claim 13, wherein said specific binding partner is antibody 3C4.
 15. The kit of claim 13, additionally comprising an optionally labeled or immobilized TC binding ligand.
 16. The kit of claim 13, additionally comprising a plurality of holoTC solutions of known concentration.
 17. The kit of claim 13, additionally comprising instructions for the performance of said assay method.
 18. The kit of claim 13, additionally comprising a plurality of apoTC solutions of known concentration. 